Liquid Level Gauge Assembly with Integral Electronic Display

BACKGROUND OF THE INVENTION

Delivery vehicles for pressurized fuel and other liquids, such as liquefied petroleum gas (LPG), propane, butane, and so on, typically include a large holding tank located rearwardly of the cab. A fuel sending unit is typically mounted at the center of the tank above eye level of the observer. The sending unit includes a float that rides on the surface of the liquid. The float is connected to a pivoting float arm which is in turn connected to the lower end of a driven shaft that rotates about its axis in response to float movement. A driving magnet is typically located at the upper end of the driven shaft that magnetically couples with a driven magnet inside the gauge head, which is associated with an indicator, so that rotational movement of the driving magnet in response to float movement induces the driven magnet to rotate a proportional amount and rotate the indicator across a scale associated with the gauge head, to thereby display a liquid level condition of the tank to an observer.

When such fuel gauges are mounted to large storage tanks associated with transportation vehicles, such as propane delivery trucks, the gauge head is typically mounted at the rear center of the tank to minimize errors in reading. However, such a location is usually above the operator’s field of view, which makes it hard to accurately read the gauge due to parallax errors that occur when the eyes of an observer are not properly aligned with the indicator and scale.

In addition, such gauges also inconvenience an operator since the liquid level within the tank is not readily apparent unless the vehicle is parked on a level surface and the operator exits the cab and walks to the rear of the vehicle to observe the gauge reading. Even when the gauge reading can be manually observed, it may not be accurate within acceptable limits unless compensation of liquid level or volume is manually calculated based on the specific gravity of the particular liquid within the tank, which can be affected by temperature. Accordingly, an operator must have knowledge of the contents of the tank, its specific gravity at a set temperature, and expansion or contraction of the volume based on changes in specific gravity for a particular fluid at different temperatures. Consequently, obtaining a clear and accurate reading of the volume or level of liquid within such storage tanks can be both a difficult and time-consuming task.

It would therefore be desirous to provide a simple, straight forward solution that would reduce or eliminate parallax reading errors while avoiding high development and manufacturing costs associated with redesigning the gauge head, fuel sending unit and/or tank.

SUMMARY OF THE INVENTION

In accordance with one aspect of the invention, an electronic gauge assembly for indicating liquid level within a tank, the gauge assembly being operatively connectable to a liquid level sensor probe, and comprising a mounting base adapted for connection to the tank, a housing connected to the mounting base, an electronic display located in the housing and having a first display portion for displaying a liquid level condition within the tank, and a first electronic sensor connected to the housing. The first electronic sensor is couplable to the liquid level sensor probe such that a change in the liquid level sensor probe due to a change in liquid level causes a change in electronic state of the first electronic sensor. A processor is in communication with the first electronic sensor for determining a first liquid level condition within the tank based on the change in state. A second electronic sensor for detecting a temperature of the liquid within the tank is also in communication with the processor. The processor includes means for calculating a second temperature-compensated liquid level condition based on the first liquid level condition and the temperature of the liquid, and sending signals representing the second liquid level condition to the first display portion for displaying the temperature-compensated liquid level condition.

In accordance with a further aspect of the invention, a method of measuring and displaying liquid within a tank includes providing an electronic gauge assembly having a processor in communication with a memory, an electronic display, a first sensor for sensing liquid level and a second sensor for sensing temperature of the liquid, determining a liquid level condition of the tank with the first sensor, determining a temperature of the liquid within the tank with the second sensor, calculating, with the processor, a temperature-corrected liquid level condition of the tank by correlating first information stored in the memory related to geometry of the tank and volume of liquid at any given liquid height, and correlating second information stored in the memory related to volume expansion and contraction for a range of temperatures, displaying at least one of temperature-corrected liquid level and temperature-corrected liquid volume on the electronic display, and communicating at least one of the temperature-corrected liquid level and volume wirelessly to a remote device.

Other aspects, objects and advantages of the invention will become apparent upon further study of the following description in conjunction with the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The following detailed description of the preferred embodiments of the present invention will be best understood when considered in conjunction with the accompanying drawings, wherein like designations denote like elements throughout the drawings, and wherein:

FIG. 1 is a schematic rear isometric view of a bobtail, transport, or other vehicle having a tank for transporting and delivering fuel or other liquid, together with a liquid level transducer having an electronic gauge assembly in accordance with an exemplary embodiment of the invention mounted on the tank;

FIG. 1A is an enlarged rear elevational view thereof taken along line 1A-1A of FIG. 1 showing the electronic gauge assembly in communication with a wireless temperature sensor located in a thermowell formed in the tank in accordance with an exemplary embodiment of the invention;

FIG. 2 is a front isometric exploded view of the electronic gauge assembly;

FIG. 3 is an enlarged front elevational view of the electronic gauge assembly of FIG. 1 illustrating exemplary information that can be shown on different display portions associated with the gauge assembly;

FIG. 4 is an enlarged front isometric view of the electronic gauge assembly in accordance with the invention;

FIG. 5 is a sectional view thereof taken along line 5-5 of FIG. 4;

FIG. 6 is a block diagram of electronic components associated with the electronic gauge assembly;

FIG. 7 is a block diagram of electronic components associated with a smart device, such as a smartphone, tablet, or the like for both wirelessly receiving information from the electronic gauge assembly and transmitting information and instructions thereto from the smart device for controlling display of the exemplary information;

FIG. 8 is a top isometric view of a smart device for wireless communication with the electronic gauge assembly and illustrating exemplary information that can be remotely displayed for the storage tank and its contents;

FIG. 9 is a rear isometric view of the liquid level transducer having a tank mounting head connected to the electronic gauge assembly of the invention and a sensing probe assembly;

FIG. 10 is a rear isometric exploded view of the sensing probe assembly of the liquid level transducer of FIG. 9;

FIG. 11 is a top plan view of the sensing probe assembly;

FIG. 12 is a side elevational sectional view thereof in taken along line 12-12 of FIG. 11 ;

FIG. 13 is a longitudinal sectional view of the liquid level transducer taken along line 13-13 of

FIG. 9;

FIG. 14 is a front elevational view of an electronic gauge assembly in accordance with a further exemplary embodiment of the invention illustrating exemplary information that can be shown on different display portions associated with the gauge assembly;

FIG. 15 is a front isometric view of a thermowell assembly for mounting to the wall of a tank, such as shown in FIG. 1 , and including a temperature sensor extending therefrom and into the tank for measuring the temperature of the fluid within the tank;

FIG. 16 is a longitudinal sectional view of the thermowell assembly taken along line 16-16 of FIG.

15; and

FIGS. 17A through 17H illustrate different exemplary display configurations associated with an application-specific program for monitoring the contents of one or more tanks based in part on information wirelessly received from the electronic gauge assembly, as well as sending information to the gauge assembly for directly displaying liquid level condition based on temperature, specific gravity, tank strapping information, and so on.

It is noted that the drawings are intended to depict only exemplary embodiments of the invention and therefore should not be considered as limiting the scope thereof. It is further noted that the drawings may not be to scale. The invention will now be described in greater detail with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE INVENTION

Referring now to the drawings, and to FIGS. 1 and 2 in particular, a liquid level transducer 10 having an electronic gauge assembly 12 with an exemplary attached sensing probe assembly 15 (FIG. 9) in accordance with an exemplary embodiment of the invention is shown connected to a refueling vehicle 14 or the like. The vehicle 14 is only partially represented in FIG. 1 and shows the rearward portion of a bobtail truck or transport trailer having a frame 16 supported on wheels 18, a wheel guard or fender 20 extending along the frame and partially around the front and rear of the wheels, a rear bumper 22 connected to the frame 14, mud flaps 24 extending downwardly from the bumper 22, tail light assemblies 26 extending laterally from opposite sides of the frame 16, and a holding tank 28 supported on the frame 16. The tank 28 includes a generally cylindrical tank section 30 with a semispherical rear tank section 32. A manway opening (not shown) is sealed by a manway cover 34 located on the rear tank section 32 above the transducer 10 for allowing manual access into the tank 28. A shield 38 for protecting and shading the electronic gauge assembly 12 of the transducer 10 is mounted on the rear tank section 32 above the gauge assembly.

The tank 28 can contain, but is not limited to, liquid propane gas (LPG), methane gas, butane gas, natural gas, GLP, and other liquefied gases or combinations thereof under pressure, other cryogenic or non-cryogenic fluids, and so on. The vehicle 14 is intended to carry a large quantity of fuel or other liquid for refilling smaller tanks, such as permanently installed commercial or residential propane tanks, for delivering fuel to a home, vehicle, and other tanks or the like, as is well-known. The manway cover 34 extends over and seals the manway opening (not shown) through a series of peripherally located fasteners 36 and one or more seals (not shown) to prevent loss of pressurized gas or liquid when in service. The tank 26 may include one or more manway openings and covers at other locations along the tank, such as when the tank is divided into several sections or segments, as is well known. It will be understood that the present invention is not limited to the particular tank configuration as shown, but can be associated with any above-ground tank, whether stationary or transportable, where convenience in accessing information of one or more tanks and sending fluid information to the electronic gauge assembly 12 associated with one or more tanks is desirous. In that regard, the liquid level transducer 10, including the electronic gauge assembly 12 and related sensors as will be described, can be mounted along the side of a tank or at any other position for measuring and displaying the condition of the liquid in the tank and/or one or more separate compartments of the tank when associated with multi- compartmented tanks.

Referring to FIG. 1 , a user 40 is illustrated standing next to the vehicle 14 and facing away from information displayed on the electronic gauge assembly 12, yet able to receive and view such information on a display 45 associated with a smart device 46, such as a smartphone, tablet, or the like, via wireless communications, such as radio frequency (RF) communications, as schematically represented by communication lines 42, 44 in FIG. 1 . The user 40 may be any person associated with the vehicle or tank, such as an operator, inspector, refueling technician, and so on. The readily available information can be viewed anywhere the RF carrier signal can be broadcast, including inside the cab (not shown) of the vehicle 17, or within a broadcast range of the RF transceiver 50 (FIG. 12) of the electronic gauge assembly 12. Accordingly, the user 40 need not walk to the back (or side) of a tank to retrieve vital tank information but is capable of receiving that information anywhere a wireless carrier signal can be transmitted and received by the user’s device 46, as well as sending information and instructions to the electronic gauge assembly, as will be described in further detail below.

With particular reference to FIGS. 2-5, the electronic gauge assembly 12 preferably includes a rear housing portion 52, a sensor assembly 54 connected to the rear housing portion 52, an electronic assembly 56 (FIG. 2) including a printed circuit board (PCB) 58 with various electronic components (not shown) connected thereto, as will be described in greater detail below, a display assembly 59 includes a first display portion 60 connected to the PCB, a second display portion 62 located above the first display portion 60 and also connected to the PCB 58, a transparent protective lens 64 to protect the display portions, and a front housing portion or bezel 66 connected to the lens 64 and the rear housing portion 52 for enclosing the above-described components. An electrical receptacle 68 is attached to the rear housing portion 52 and includes a plurality of pins 70 (FIG. 4) associated with the electronic assembly 56 for connection with a wiring harness (not shown) associated with the vehicle, system, machine, and so on, associated with the tank. The wiring harness (not shown) is connected to a power supply 72 (FIG. 6), such as the power supply of a vehicle, external battery, line power, and so on, for example, for providing electrical power to the electronic assembly 56 and displays 60 and 62. The electronic assembly 56 is also capable of transmitting, via the receptacle 68 and wiring harness, signals to an external display (not shown) indicative of conditions inside the tank 28 (FIG. 1) including temperature, pressure, liquid type, specific gravity, density, liquid level, vapor space, and so on, ambient conditions outside of the tank such as temperature, humidity, atmospheric pressure, vehicle tilt, and so on, as well as other conditions and/or measurements. The external display may be associated with the vehicle, a portable display associated with a smartphone or tablet 46 (FIG. 1) or other smart device, and so on.

The rear housing 52 includes a rear wall 74 with a depression 76 having first generally circular depression portion 78 for receiving the sensor assembly 54, and a second generally elongate depression portion 80 for accommodating the shape of the receptacle 68. A continuous side wall 82 extends forwardly from the rear wall 74 and includes a lower opening 84 that receives the side wall 86 of the receptacle 68. A bottom wall 88 of the receptacle rests against the side wall 82 of the rear housing 52 and is connected thereto through mechanical fastening, adhesive bonding, ultrasonic welding or any other connection means so that the receptacle 68 stays in place when connecting or connected to a wiring harness (not shown) of the vehicle or system associated with the tank 28. Spaced mounting bosses 90 and 92 extend forwardly from the rear wall 74 of the rear housing 52 and include openings 94. Corresponding openings 95 (FIG. 2) are also formed in the front bezel 66 and openings 101 are formed in the lens 64. Threaded fasteners 97 extend through the openings 95 of the front bezel 66, openings 101 of the lens 64, and the openings 94 of the bosses 90, 92 of the rear housing 52 for securing together the electronic gauge assembly 12. Mounting apertures 96 are also formed in the rear wall 74 that align with corresponding mounting apertures 98 formed in the PCB 58 and mounting apertures 100 formed in the first display portion 60 for mounting the first display portion 60 to the PCB 58 and the rear housing 52 via threaded fasteners 99 (only two shown for clarity in FIG. 2), standoffs, or the like that extend through the apertures 100, 98 and 96, respectively.

The PCB 58 includes side depressions 102 and 104 for receiving the mounting bosses 90, 92 respectively. Various electronic components of the electronic assembly 56 are connected to a rear side 106 of the PCB 58, while the first display portion 60 and second display portion 62 are connected to a front side 108 of the PCB 58 for viewing by an observer through the transparent protective lens 64.

As best shown in FIG. 5, the generally circular depression portion 78 formed in the rear wall 74 of the rear housing 52 has retainers 1 10, 1 12, and 1 14 for holding a sensor PCB 1 16 of the sensor assembly 54. The sensor assembly 54 also includes a sensor 1 18 or the like, preferably in the form of a magnetic field sensor, for detecting rotational movement of an actuator 120, preferably comprising a magnet, through the rear wall 74 of the rear housing 52. The magnet 120 is connected to an upper end of a shaft 122 for rotation therewith about a first rotational axis 121 of the shaft 122, as represented by arrows 124, upon a change in liquid level inside the tank, as will be described in greater detail below.

The actuator magnet 120 can have an anomaly 126, shown as a slot for example, so that the magnetic field is non-uniform. Other anomalies can include thicker and thinner magnetic sections, sloped magnetic surfaces, rectangular-shaped magnets, magnets having different polarity signatures, one or more magnets that are offset from the first rotational axis 121 , and so on. It will be understood that the anomaly may be removed when certain types of magnetic sensors are used.

By way of example, magnetic sensors can include, but are not limited to, one or more solid state magnetic flux field sensors, Hall effect sensors, magnetoresistive (MR) sensors, anisotropic MR (AMR) sensors, giant magneto resistance (GMR) sensors, solid state Micro-Electro-Mechanical Systems (MEMS), magnetic switches, as well as nonmagnetic sensing technologies such as proximity detectors using capacitance, optical, or other measurement technologies, and so on. With the use of the above sensors, it may not be necessary to have the sensor in alignment with the central axis of rotation of the magnet, or a plurality of sensors, since a single Hall effect IC may be sufficient to determine the position of the magnet and thus the level of liquid within the container.

It will be appreciated that the invention is not limited to actuators and sensors for generating and sensing magnetic fields or changes in magnetic fields during rotation of the actuator 120, but may include other types of actuators and sensors for determining liquid level or other tank conditions. For example, the sensor 1 18 can be in the form of one or more optical sensors for use with optical actuators, such as LED's or other light source, as well as other contactless actuator/sensor arrangements to remotely change the electrical state of the sensor to thereby generate a liquid level signal in response to rotational movement of the shaft 122. In the event that optical actuators/sensors are used, the housing can be formed of a material that is translucent or transparent to the wavelength of the light source so that the sensor can readily detect movement of the light source as the liquid level in the container rises and falls.

Referring to FIGS. 2 and 3, the first display portion 60 preferably comprises electronic display technology such as LCD, LED, or OLED panels, as is well-known, or new display technology that may become available. The display portion 60 is divided into display sections for indicating various conditions of the tank 28 (FIG. 1), including a first exemplary display section 130 that shows the level and/or volume of the tank as a temperature-compensated percentage where 0% is an empty tank condition and 100% is a full tank condition. The first section 130 can additionally and/or alternatively display remaining gallons (or liters) of liquid within the tank, the volume of a gaseous phase of the liquid or the vapor content of the tank above the liquid, which is important for pressurized fuels in both liquid and gaseous states such as propane, natural gas, and so on, as well as other information relating to the contents of the tank and/or conditions within the tank. The display of different information may be controlled in the first section 130 by scroll buttons (not shown), the provision of a touch-sensitive display for the first display portion 60 where swiping actions by the user will scroll to different images representing the tank information, as well as control of the display portion 60 remotely via a smart device, as well as other techniques, hardware, and software methods for sequentially displaying different information. Further details with respect to exemplary information and instructions on an interactive display associated with a smart device will be described with respect to FIGS. 17A through 17F.

The first display portion 60 also includes a second exemplary display section 132 that shows the specific gravity of the liquid within the tank, as well as other information including ambient temperature, tank temperature, tank pressure, and so on, again through sequential scrolling techniques as discussed above. A third exemplary display section 134 shows the internal tank temperature in Fahrenheit, and alternatively in Celsius, and can additionally or alternatively display the temperature of the gaseous phase and/or liquid phase within the tank, the outside ambient temperature, tank pressure, outside ambient pressure, and so on. A fourth exemplary display section 135 shows tank temperature displayed in Celsius, but may also or alternatively display other information as discussed above. A fifth exemplary display section 136 and sixth exemplary display section 138 preferably include a first alarm indicator 140 and a second alarm indicator 142, respectively, which may comprise one or more LED’s that illuminate or flash when certain conditions have or are occurring that may be of concern to a user. For example, such conditions can include excessively high or low levels of liquid in the tank, tank pressure that drops below a low threshold or exceeds a high threshold, and so on. Further alarm indicators can also or alternatively be used for indicating that fill or distribution valves are not fully closed or open, or that the vehicle is improperly parked (with the vehicle in neutral or without the emergency brake set for example), as well as other conditions that might be of concern to a user. Such conditions can be more fully displayed in the first and/or second display sections, or further display sections for indicating such conditions can be implemented.

A seventh display section 144 can be used for permanently or temporarily displaying a company name, advertisements, instructions and warnings, and so on. The seventh display section can be made by placing or adhering a printed adhesive label on the transparent lens 64 (FIG. 2) or other substrate, and/or by silk-screening such information onto the lens or other substrate. To that end, additional LED’s 146 can be provided behind the lens 64 within the seventh display section 144 for back-lighting the printed matter of the seventh display section 144.

It will be understood that more or less display sections can be used and that more or less information can be displayed without departing from the spirit and scope of the invention.

The second display portion 62 preferably comprises a series of bargraph display sections 150, 152, 154, and 156 for example, each bargraph having ten LED segments 158. Each LED segment represents a predetermined percent of temperature-compensated volume of liquid in the tank. A scale 160 extends along the length of the bargraph display sections for indicating the percent volume by observing the number of LED segments 158 that are illuminated next to the scale 160. As shown in FIG. 3, the cross-hatching of the LED segments up to about 90% represent a green color, meaning that the contents of the tank are at an acceptable volume or level. Likewise, the cross-hatching of the LED segments around 90% and above represent a red LED color, indicating that the contents of the tank are approaching or above an unacceptable volume or level. Since liquid expands with increase in temperature, it is standard practice to fill the tank to a level below completely full to allow for expansion of liquid. The second display portion 62 of the invention, together with the alarm sections 140, 142 of the first display portion 60, ensure that a user is aware of the tank 28 (FIG. 1) being too empty or too full, so appropriate action can be taken.

It will be understood that the LED segments can be provided on the PCB 56 (FIG. 2) as a series of individual LED’s rather than the bargraph displays. It will be further understood that the colors of the LED segments are not limited to green and red, but can emit light at any color without departing from the spirit and scope of the invention.

With reference now to FIG. 6, the electronics assembly 56 for determining various tank and ambient conditions and for driving the display portions 60 and 62 preferably includes a processor 174, the sensor 1 18 for detecting liquid level (labeled“Sensor 1”), as well as other sensors and electronic components connected to the processor for determining corrected level and volume of liquid within the tank based on the specific gravity of the particular liquid being measured, the temperature of the liquid, tank strapping information, and so on.

Turning now to FIGS. 1A, 6, 15 and 16, a temperature sensing assembly 175 (not shown in FIG. 6) is mounted to the wall 32 or other position on the tank where measurement of the temperature of the liquid within the tank is suitable. The sensing assembly 175 includes a thermowell housing 177 (FIGS. 15 and 16) supporting a temperature sensor 176 (also labeled“Sensor 2” in FIG. 6). The housing 177 includes a mounting head 179 for installation on the tank wall and a probe 181 extending from the mounting head and into the tank. An end cap 181 A is connected to the free end of the probe 181 and seals the inner space 181 B of the probe to prevent the ingress of liquid into the inner space and the egress of thermally conductive material therefrom, such as antifreeze, copper grease or other thermally conductive grease, and so on, so that the temperature of the liquid is transferred with little conductive heat loss through the probe material. The temperature sensor 176 is located outside of the probe 181 so as to be in direct contact with the liquid being measured, but may be located within the sealed probe or thermowell housing 177. Electrical conductors 176A and 176B extend from the sensor 176, through the filled inner space 181 B of the probe 181 , and into the mounting head where signals are received by an electronics assembly located in the thermowell housing 177 for processing and transmitting temperature signals associated with the fluid in the tank.

The mounting head 179 preferably includes outer NPT threads 183 or the like for mating with similar inner NPT threads 185 or the like formed in an opening 187 of the tank wall 32 (FIGS. 1 A, 16) or other suitable position with respect to the tank to support the housing 177 and seal the opening 187.

As shown in FIG. 1 A, an optional second opening 187A with NPT threads 185A (shown in phantom line) can be formed in the tank wall for mounting a pressure sensing assembly for directly measuring pressure inside the tank. Other similar openings for other sensors can additionally or alternatively be provided for sensing the type of fluid in the tank, different immiscible liquids that may be located in the tank, such as propane and water, the quality of the liquid, the color or clarity of the liquid, the contents of the vapor space above the liquid, and so on. Such sensors can also communicate wirelessly with the electronic gauge assembly 12.

The mounting head 179 of the thermowell housing 177 includes a bottom wall 193 spaced from the threads 183, a side wall 191 extending outwardly from the bottom wall 193, and an end cap 189 that seals against the side wall 191 to form a sealed interior space 195 (FIG. 16). A printed circuit board (PCB) 197 is located within the interior space 195 and includes a microprocessor 199 for receiving signals from the temperature sensor 176, a transceiver 201 with chip antenna (not shown) or the like for wirelessly transmitting temperature information to the electronic gauge assembly 12 at radio frequencies, such as in the Bluetooth frequency band, e.g. the 2.4 GHz radio frequency band, and optionally to the smart device, as well as receiving signals from the electronic gauge assembly 12 to wake up the processor, receive temperature readings from the sensor 176, and transmit the temperature readings to the electronic gauge assembly for correcting the liquid level and/or volume measurement inside the tank. A power supply 203 is also located in the interior space 195 and is electrically connected to the PCB to power the microprocessor 199, transceiver 201 , and other electronic components. The power supply can comprise one or more primary lithium thionyl Chloride batteries, which have a high energy density and are capable of supplying electrical power to low-power electronic circuitry for many years. It will be understood that other battery technologies and/or means for supply power can be used, including rechargeable batteries of various formulations, self-charging batteries and devices, electromagnetic induction generators and associated storage capacitors, solar cells, as well as other regenerative energy harvesting devices, and so on.

The temperature sensor 176 preferably includes a resistance temperature detector (RTD) probe that produces an analog signal in proportion to temperature, which is received by the microprocessor 199 for transmitting to the electronic gauge assembly 12. It will be understood however that other temperature sensors can be used without departing from the spirit and scope of the invention, including but not limited to, thermocouples, diodes, thermocouples, negative temperature coefficient (NTC) or positive temperature coefficient (PTC) thermistors, silicon bandgap temperature sensors, semiconductor- based analog and/or digital temperature sensors, and so on. One or more of the above-described components, including the microprocessor 199, transceiver 201 , connection for temperature sensor 176, and other related electronic components, can be embodied as a system on chip (SOC) device. The mounting head located within the. Preferably, the transceiver 201 transmits temperature data at Bluetooth frequencies such that the above-described assembly comprises a low-energy Bluetooth (BLE) device for transmitting temperature of the fluid in the tank. It will be understood that other frequencies can be used for wirelessly communicating the temperature information to the electronic gauge assembly 12. Accordingly, the temperature sensing assembly 175 is preferably a stand-alone unit that operates independently of the electronic gauge assembly 12, with the exception of signals that may be sent from the gauge assembly to wake up the temperature sensing assembly 175 and query real-time temperature information therefrom, including discrete temperature signals representative of a single temperature reading, a running average of temperatures over a preset time period, and so on. If, after a

predetermined time period the temperature sensor assembly 175 does not receive any transmissions from the gauge assembly 12, the sensor assembly 175 can return to“sleep” mode in a very low-power state to conserve battery power. The temperature information can be used with a look-up table stored in memory 194 (FIG. 6) of the electronic gauge assembly 12 to adjust the actual volume of liquid based on the type of liquid in the tank and the temperature of the liquid. For example, propane, iso-Butane, n- Butane, and NH3 will have different temperature compensation factors for the same temperature, with the exception of 60 degrees Fahrenheit, where the actual volume or level of fluid in the tank is at unity for each liquid type as a base reference. Below 60 degrees, each liquid will have a correction factor above unity, which generally increases as the liquid expands under lowering temperatures. Above 60 degrees, each liquid will have a correction factor below unity, which generally decreases as the temperature rises. Accordingly, when displaying temperature-compensated liquid level, a simple math operation is performed with the processor based on the detected temperature and the measured liquid level to obtain actual liquid level.

In accordance with one exemplary embodiment of the invention, since many storage tanks are strapped, strapping information for the particular tank associated with the electronic gauge assembly 12 can be uploaded as a strapping table into permanent memory and used to determine tank contents in gallons, liters, and/or other units of volume. Since tanks are available in a variety of different tank sizes and shapes, strapping information for different tanks would also be different. When the actual volume in gallons or liters is displayed, strapping information relating to tank geometry and the volume of liquid at a particular height with respect to the geometry is also stored in a look-up table for access by the processor. Accordingly, when the processor determines temperature compensated liquid height, the strapping lookup table is accessed by the processor to correlate the temperature-compensated height with actual volume at that compensated height, thereby obtaining temperature-compensated volume in gallons, liters, or other units of volume. Accordingly, the present invention can display temperature- compensated volume of the liquid within the tank.

A pressure sensor 178 (labeled“Sensor 3”) can be provided for measuring the internal pressure of the tank. The pressure sensor 178 can be directly associated with the electronic gauge assembly 12 or embodied as an independently operated sensing assembly much like the temperature sensing assembly

175, and installed in a threaded opening 187A (FIG. 1A), as previously described. The pressure information may then be wirelessly transmitted to the electronic gauge assembly 12 in a manner similar to the temperature sensor 176. Other sensors can be provided as well, including sensor 180 (shown in dashed line and labeled“Sensor n”) located inside and outside of the tank 28 (FIG. 1) for determining various conditions, such as ambient temperature and pressure outside of the tank, whether or not filling and/or distribution valves are fully closed, and so on. The designation“Sensor n” refers to any number of sensors that can be used to measure different conditions of the tank, the vehicle or system associated with the tank, as well as ambient conditions outside of the tank, such signals being transmitted either wirelessly or electronically to the electronic gauge assembly 12 and/or the smart device 46.

Although a particular embodiment for the temperature sensing assembly 175 and optionally a pressure sensing assembly have been shown and described, it will be understood that other mounting arrangements as well as other temperature and/or pressure sensing probe configurations can be used without departing from the spirit and scope of the invention. For example, a ½-inch NPT or ¾-inch NPT threaded mounting opening are common on many types of storage and transport tanks and therefore it is within the purview of the present invention to provide appropriate mounting heads for any tank mounting configuration for connecting the temperature sensing assembly and optionally the pressure sensing assembly to the tank wall at any suitable position.

Amplifier and offset control circuitry 182 interfaces between the processor 174 and sensors 1 18,

176, 178, 180, and so on, for conditioning the signals from the sensors prior to being received and processed within the processor 174. It will be understood that the amplifier and offset control circuitry 182 may alternatively form part of the processor software or may be eliminated without departing from the spirit and scope of the invention.

A radio frequency (RF) transceiver 50 is also connected to the processor 74 for sending signals to the display 45 (FIG. 1) of the smart device or remote display unit 46 for displaying various

measurement data from the sensors 1 18, 176, 178, 180, as well as other sensors, as will be described. The RF transceiver 50 can also receive signals from the remote smart device 46 for initiating various functions such as remotely turning on and off the display portions 60 and 62, verifying the receipt of transmitted information, loading software updates to the electronic gauge assembly 12, changing the arrangement and number of the display portions for a customized appearance, and so on.

In accordance with a preferred embodiment of the invention, the RF transceiver comprises a Bluetooth low energy (BLE) module for communicating with smart devices via the same protocol, which may in turn be connected to the Internet via Wi-Fi, so that one or multiple electronic gauge assemblies can be monitored, updated, calibrated, and effect the electronic transfer of tank information remotely via the Internet on any device with a compatible platform.

In accordance with a further embodiment of the invention, the RF transceiver comprises a Wi-Fi device capable of directly communicating with the Internet for remotely accomplishing the above- described functions. In this embodiment, the RF transceiver broadcasts over Wi-Fi frequencies and also has a dedicated modem or other device for transmitting and receiving on the 3G, 4G or other cellular networks to access to the Internet when such services are not readily available. It is contemplated that other RF transceivers can be used with a variety of different carrier frequencies, such as radio bands with 433.92 MHz, 915MHz, and 2400 MHz frequencies, short range devices at 315 MHz and 868 MHz frequencies, as well as defined protocol communications via ZigBee™, Bluetooth low energy (BLE), and Wi-Fi, at 2.4 Ghz, 3.6Ghz, and/or 5Ghz, and/or any other suitable protocol.

The RF transceiver 50 is preferably located at a position on the PCB 56 (FIG. 2) that minimizes RF interference and maximizes the distance or range over which the signals can be transmitted. A user input, such as one or more push-button switches 184 (FIG. 6), can be mounted on the PCB 56 for manipulation by a user to selectively turn on and off the displays, scroll through different information or menu options on the displays, as well as other functions, including but not limited to, entering a learn mode to couple the electronic gauge assembly 12 with a particular smart device 46 (FIG. 1), entering a calibration routine or other functions relating to the contents of the tank, and so on.

The transceiver 50 can also receive signals from the remote smart device 46 for initiating various functions, as previously described. By way of example, the low energy Bluetooth connection between the smart device and the electronic gauge assembly includes a platform-specific application (app) on the smart device for configuring the electronic gauge assembly including the display portions 60 and 62. Thus, the user is able to input key setup parameters for the gauge including, but not limited to: entering the specific gravity of the liquid in the tank, selection of preferred temperature units: °C or °F for example, Alarm 1 on/off selection, Alarm 2 on/off selection, Alarm 1 trigger percentage, Alarm 1 trigger slope (increasing level or decreasing level), Alarm 1 delay, e.g. a predetermined time period, such as 30 seconds for example only, that the alarm condition has been met prior to activating the alarm, Alarm 2 trigger percentage, Alarm 2 trigger slope (increasing level or decreasing level), Alarm 2 delay (similar to Alarm 1 delay), and so on. The tank geometry specific data correlated to liquid level and volume for both uncompensated and temperature compensated level can be provided via the BLE link, the tank temperature can also be provided via BLE link in the desired units, turning on and off advertising information on the display, and so forth. This last-mentioned feature is to allow advertisements to be displayed on the bobtail while traveling for example, so that other drivers may be exposed to advertising, which may be an additional source of revenue for companies and individuals using the electronic gauge assembly.

A GPS unit 186 can also be provided to determine instantaneous velocity as well as the location of the vehicle at all times. This information can be relayed to the remote smart device 46 and/or a remote location for monitoring by a control station or the like for determining the location of a fleet of bobtails or the like. The GPS unit can also be useful for alerting a driver when, based upon the calculated remaining gallons of liquid, whether the driver can continue with a refilling route or return to the base station for filling the storage tank.

A three-axis accelerometer 188 can also be provided to determine acceleration, deceleration, instantaneous velocity, centrifugal forces experienced while turning through curved sections of a roadway, and so on. Data from the accelerometer can be used to determine actual liquid level despite changes in the upper surface of the liquid due to acceleration forces to ensure that a steady level or volume of fluid is displayed.

A three-axis tilt sensor 190 is preferably provided for determining whether the vehicle, and thus the tank, is on a sloped surface, both lengthwise and width-wise, which would effectively change the plane of the liquid upper surface with respect to a sensor that uses the upper surface to determine liquid level or volume. With the angle of the slope being known, as well as the geometry of the tank, the processor 174 can be used to calculate actual level so that errors in displaying incorrect liquid level or volume are minimized.

A three-axis gyroscope 192 can also be provided to determine the upper surface of the liquid with respect to the tank geometry and angle, as the upper surface will always be perpendicular to a gravitational force vector, while the vehicle and tank may not. Accordingly, the gyroscope 192 is useful for ensuring that actual tank volume or level is displayed. Although the accelerometer, tilt sensor and gyroscope are shown as separate units in FIG. 6, it will be understood that a 9-axis accelerometer / gyroscope / tilt sensor SOC unit can be used. Such devices are widely available at relatively low cost and can be interfaced with the processor 174 for calibrating the liquid level and/or volume of liquid in the tank with practically any scenario to ensure accurate display of the tank condition, whether the tank and its contents are stationary or moving, whether on flat or sloped surfaces, and so on. The data can be gathered wirelessly or electronically from the various sensors and stored in the memory 194 associated with the processor 174. A data output interface 196 can be provided in order to store, process and display the recorded data on a display, such as display portions 60 and 62 (FIG. 3), as previously described.

The real-time compensation process associated with ensuring accurate liquid level and/or liquid volume within the tank can be gathered and processed through known data processing techniques using computer algorithms or software for various platforms and can be provided as computer readable software on various media storage devices for downloading into and operating on a smartphone, a computer, display, or the like, including but not limited to, hard drives, Internet websites, thumb drives, flash memory devices, CD's, and so on.

In accordance with a further feature of the invention, with the above-described electronics and software implementation both embedded in the electronic gauge assembly 12 and the user-specific app on the smart device, the calculation of vapor content within the tank 28 is possible. To do so, the processor accesses the strapping information of the particular tank of interest where tank geometry is correlated to liquid height and volume, as well as tank pressure information from the pressure sensor 178 (FIG. 6), the volume of the vapor space above the liquid can be calculated. This is especially advantageous for liquids such as propane.

By way of example, if it is known that the tank 28 has a 10,000-gallon water capacity, and the temperature-compensated level reading is calculated at 75% full, and the tank pressure is 100 psig, the processor 174 (FIG. 6) accesses a vapor space lookup table where gauge pressure is correlated to gallons (or other volume units) for the vapor space. A simple mathematical operation is performed by the processor by multiplying the gallons or other unit associated with the lookup table by the water capacity of the tank. For the present example, for 100 psig tank pressure, the value in the lookup table is 0.0287 gallon. The mathematical function would therefore be multiplying gallons from the lookup table by the water capacity, e.g. 0.0287 x 10,000 = 287. Since the vapor space is equal to 25% of the total volume (since the temperature-compensated liquid level was calculated at 75% in the example above), the processor multiplies gallons by the vapor space, for example, 287 gallons x 25% = 72 gallons of vapor space. The following vapor lookup table for propane is given by way of example only, and is based on typical value of 36.39 cubic feet of gas to one gallon of LPG:

Gauge Pressure _ Gallons

200 .0537

150 .0412

100 .0287

50 .0162

10 .0062

0 .0037

In accordance with a further embodiment of the invention, a separate pressure sensor may not be needed as the processor can calculate the tank pressure with the following lookup table correlating propane temperature with pressure for example as follows:

°F PSIG

-20 13.5

0 28

20 47

40 72

60 102

80 140

100 196

Having a more complete picture of the amount of propane or the like in the tank (in both liquid and vapor phases) is advantageous to the user, as the vapor phase of propane and similar fuels is most often used to run propane-powered vehicles and equipment.

It will be understood that the various measured and calculated parameters as described above are given by way of example only and are not intended to be an exhaustive list. Software techniques and methods for accurately determining the liquid level, volume and other tank conditions as discussed above can be implemented in digital electronic circuitry, or in computer hardware, firmware, software, or combinations thereof. Apparatus may be implemented in a computer program product tangibly embodied in a machine-readable storage device for execution by a programmable processor; and the above- described methods may be performed by a programmable processor executing a program of instructions to perform functions by operating on input data and generating output. Further embodiments may advantageously be implemented in one or more computer programs that are executable on a programmable system including at least one programmable processor coupled to receive data and instructions from and transmit data and instructions to a data storage system, at least one input device, and at least one output device. Each computer program may be implemented in a high level procedural or object-oriented programming language, or in assembly or machine language, which can be compiled or interpreted. Suitable processors include, by way of example, both general and special-purpose microprocessors. Generally, a processor receives instructions and data from read-only memory and or RAM. Storage devices suitable for tangibly embodying computer program instructions and data include all forms of non-volatile memory, including by way of example semiconductor memory devices, such as EPROM, EEPROM, and flash memory devices; magnetic disks such as internal hard disks and removable disks; magneto-optical disks; and so on. Any of the foregoing may be supplemented by, or incorporated in, specially designed application specific integrated circuits (ASIC’s).

Referring to FIGS. 7 and 8, the remote smart device 46 is preferably embodied as a smartphone or tablet that can communicate via Bluetooth™ technology and/or other wireless frequencies with the electronic gauge assembly 12 via a user-specific application (app) downloaded onto the smart device. The smart device 46 includes a housing 200 (FIG. 8) that encloses an electronics section 202 (FIG. 7). A window 204 is formed in the housing 200 for exposing the touch-screen display 45, that is in turn connected to a processor 206. A RF transceiver 208, such as a BLE for example, is preferably connected to the processor 206 for receiving measurement signals from the electronic gauge assembly 12 and transmitting information related to tank geometry including strapping information and look-up tables as previously described, information for the particular liquid to be measured in the tank, program updates and instructions to the gauge assembly as previously described. A power supply 210 is connected to the processor 206 and transceiver 208. The power supply comprises one or more batteries so that the smart device 46 has portability. A user input, such as push-button switch 212A, 212B, extend from the housing 200 for manipulation by a user, together with the touch-screen 45, to selectively turn on and off the display 45 and/or 59 of the gauge assembly 12, as well as to select other functions, including but not limited to, wirelessly coupling with the electronic gauge assembly 12, selecting information to be displayed on both devices, selecting information to be transmitted to the electronic gauge assembly related to tank geometry, liquid properties, look-up tables, and so on, for use by the processor 174.

The provision of a remote display that can be carried by a user, as shown in FIG. 1 , is especially advantageous over prior art solutions that require the user to be at the rear or side of the tank to determine the amount of liquid within the tank. This is especially true of bobtails or other tanker trucks where the only liquid level gauge is located at the rear of the tank, as well as transport trailers where the only liquid level gauge is mounted on the side of the tank. Such prior art gauges are mechanical in nature and have many disadvantages when compared to the present invention, since communication of tank information to a more convenient and possibly safer location is enabled, along with liquid level or volume information that is both temperature compensated and calibrated for tilt and acceleration/deceleration forces. Such a provision also allows a user to constantly monitor tank contents and other parameters during transportation along roads that have steep upward or downward grades, curves, and other instances where acceleration and/or gravitational forces may have an incorrect influence on the measurement of liquid level and/or liquid volume within the tank. Moreover, such a provision also allows information wirelessly transmitted to the electronic gauge assembly to be completely controlled by the smart device. This allows the end user to customize the gauge assembly and accompanying display for a specific tank, liquid to be measured, and type of sensing probe used to measure the liquid level.

As shown in FIG. 8 for example, some of the information with can be displayed on the smart device 46 (and also transmitted to the electronic display 60) is a graphical image of liquid level 214, a “Liquid Level (Temp. Compensated) label 216 followed by a numeric display of the percent liquid level or volume 218. A label and numerical value for the number of gallons (or liters) remaining in the tank are displayed at 220 and 222. Likewise, a label and value for vapor volume remaining in the tank, as calculated, are displayed at 224 and 226. At 228 and 230, a label and actual value for the temperature of the liquid in the tank are displayed. AT 232 and 234, a label and numeric value for the total amount of liquid dispensed from the vehicle during the day, are displayed. At 236, a gross profit for the day’s deliveries is displayed. Of course, it will be understood that the above information is given by way of example only and the actual information can vary depending on the particular requirements of a particular tank, the properties of a particular liquid or liquids to be measured, and the particular level sensing probe being used.

Referring now to FIGS. 9-13, the sensing probe assembly 15 is shown connected to the electronic gauge assembly 12. Although a particular sensing probe and its mounting arrangement with the electronic gauge assembly 12 will be shown and described, it will be understood that the electronic gauge assembly of the present invention can be used with any float-type liquid level transducer or any solid-state liquid level transducer where liquid level signals can be transmitted to the electronic gauge assembly 12 in practically any application and/or location where indication of liquid level is desirous. Accordingly, it is anticipated that the electronic gauge assembly 12 can be used with capacitance-type liquid level probes, reed switch-type probes, and so on.

The sensing probe assembly 15 includes a gauge head 240 with a mounting base 242 adapted for mounting on the wall 243 (FIG. 13) of the tank 28 (FIG. 1). The electronic gauge assembly 12 is connected to the mounting base 242 via a pair of brackets 244 and 246 that are located between the mounting base 242 and the rear wall 74 of the rear housing 52 of the electronic gauge assembly 12. The mounting base 242 is shown as generally circular in shape and includes apertures 248 that align with apertures 250 formed in the tank wall 243. Fasteners (not shown) extend through the apertures for connecting the mounting base 242 to the wall. Instead of apertures in the tank wall, threaded studs may extend through the tall for engaging the apertures 248 of the mounting base 242 in a known manner for connecting the components together.

The sensing probe assembly 15 also includes a tubular support member 320 that extends downwardly from the gauge head 240 and houses the driven shaft 122 (FIGS. 5, 12 and 13) that in turn rotates a magnet 120 (FIG. 5) or other actuator for detection by a magnetic field sensor 1 18 or the like, as previously described. The tubular support member 320 and driven shaft 122 can be provided in different lengths to accommodate a wide variety of different tank depths.

A gear assembly 324 is located at a lower end of the tubular member 320 and includes a driving gear 326 rotatably connected to an inner yoke 330 (FIG. 10) and a driven gear 328 connected to the driven shaft 122 for rotation therewith. The driving gear 326 and driven gear 328 are coupled together such that rotational movement of the driving gear results in proportional rotational movement of the driven gear 328 and thus rotation of the shaft 122 to ultimately drive the display portions 60 and 62 (FIG. 3). The inner yoke 330 is connected to the lower end of the tubular member 320. The driving gear 326 is rotatably connected to the inner yoke 330 via a pivot pin 332 (FIG. 12) that extends through the driving gear 326 and inner yoke 330. The driving gear 326 is preferably fixedly connected to the pivot pin which is in turn rotatably connected to the inner yoke 330 about a pivot axis 334 (FIG. 9).

An outer yoke 336 includes a pair of arms 338, 340 that are fixedly connected to the pivot pin 332 for rotation therewith about the pivot axis 334. A cross member 342 extends between the arms 338, 340 and includes a threaded opening 344 (FIG. 10) for receiving the threaded end of an insert 346. A float rod 348 has a proximal end 349 that is received over the insert and secured thereto with a bolt 350 that extends through the float rod 348 and insert 346. A nut 352 is received on the end of the bolt 350 to thereby securely connect the float rod 348 to the outer yoke 336. The float rod 348 can be provided in different lengths to accommodate a wide variety of different tank sizes and configurations.

A float 354 is connected to a distal end 356 of the float rod 348 via an insert 358 that is connected to the float and received in the distal end 356 of the float rod. A bolt 360 extends through the float rod 348 and insert 358 and a nut 362 is received on the end of the bolt 360 to thereby securely connect the float 354 to the float rod 348. The float 354 can be provided in different lengths, widths, shapes, configurations, materials, densities, can be solid or hollow, and so on, to accommodate a wide variety of different liquids to be measured.

A U-shaped bracket 364 fits within the outer yoke 336 and is biased toward the gear assembly 324 by a compression spring 366 located between the cross member 342 and the bracket 364. A spring guide 368 is connected to the bracket 364 and extends into the spring 366. Stop members 370 are preferably mounted on the arms 338, 340 to limit bracket travel toward the gear assembly.

A counterweight assembly 372 is preferably connected to a distal end 374 of the outer yoke 336. The counterweight assembly 372 includes a first weight portion 378 connected to the yoke arm 338 and a second weight portion 380 connected to the yoke arm 340 via fasteners 382, such as rivets. However, it will be understood that one or both weight portions can be connected to the arms 338, 340 via threaded fasteners, clamps, welding, adhesive bonding, and other connection means, as well as being integrally formed or machined with the yoke arms, without departing from the spirit and scope of the invention. It will be further understood that a single weight portion can be used or both weight portions can be eliminated when the arms 338, 340 are sufficiently heavy to counteract the forces applied by the float and float rod. In addition, it will be understood that one of the yoke arms can be eliminated if a single yoke arm and/or weight are sufficient to counteract the float and float rod forces.

Although a particular embodiment for the sensing probe assembly 15 has been shown and described, it will be understood that other mounting arrangements as well as other sensing probe configurations can be used without departing from the spirit and scope of the invention. For example, a one-inch NPT threaded mounting opening is common on many types of holding tanks and therefore it is within the purview of the present invention to provide appropriate mounting heads for any tank mounting configuration for connecting the electronic gauge assembly and the sensing probe assembly to the tank wall.

Moreover, it will be understood that other sensing probes can be used in conjunction with the electronic gauge assembly of the invention, including but not limited to spiral rods that rotate upon linear float movement, float rods that rotate with the driven shaft as set forth for example in U.S. Application No. 15/490,881 to Herbert G. Ross, Jr. filed on April 18, 2017, the disclosure of which is hereby incorporated by reference, as well as stationary sensing probes that use reed switches, capacitance, resistance, time domain reflectometry, heated wire or plate technology, and so on, without departing from the spirit and scope of the invention. Another suitable exemplary liquid level sensing probe is disclosed in U.S. Patent No. 5,357,815 assigned to Rochester Gauges, Inc., the disclosure of which is hereby incorporated by reference. Details of another suitable sensing probe can be found in U.S. Patent No. 6,041 ,650 assigned to Rochester Gauges, Inc., the disclosure of which is hereby incorporated by reference. Accordingly, it will be understood that other sensing probes can be used with the electronic gauge assembly of the present invention without departing from the spirit and scope thereof.

Referring now to FIG. 14, an electronic gauge assembly 400 for use in the liquid level transducer 10 in accordance with a further exemplary embodiment of the invention is illustrated. As in the previous embodiment, the electronic gauge assembly 400 is connected to, and operably associated with, the sensing probe assembly 15 (FIG. 9) or the like for determining and displaying the volume of liquid level within the tank, the temperature of the liquid, specific gravity, and other parameters indicative of the liquid level condition, composition, quality, and so on.

The electronic gauge assembly 400 is somewhat similar in construction to the electronic gauge assembly 12 previously described, and includes an with a rear housing portion and a liquid level sensor assembly with PCB and associated electronics, as shown in FIGS. 2 and 3-5. A display assembly 402 includes a first display portion 404 connected to the PCB and a second display portion 406 located above the first display portion 404 and also connected to the PCB. A transparent protective lens (not shown) is provided to protect the display portions, and a front housing portion 408 is circular in shape and includes an outer circular mounting flange 409 with openings (not shown) for receiving fasteners 410 that extend through the flange and the rear housing portion (not shown) in a manner similar to fasteners 97 (FIG. 3) previously described, for enclosing the above-described components. The front housing portion 408 also include a circular bezel 41 1 extending upwardly from the mounting flange 409 for enclosing the lens (not shown) and the associated electronics, as previously described. The circular bezel defines a circular window 415 for viewing the display portions 404 and 406.

A wiring cable or harness 412 extends from the electronic gauge assembly 400 and is associated with the tank’s vehicle, system, or machine for providing power thereto and signals therefrom to a remotely wired external display (not shown) indicative of conditions inside the tank 28 (FIG. 1) including temperature, pressure, liquid type, specific gravity, density, liquid level, vapor space, and so on, ambient conditions outside of the tank such as temperature, humidity, atmospheric pressure, vehicle tilt, and so on, as well as other conditions and/or measurements.

The first display portion 404 and second display portion 406 preferably comprise electronic display panel 405 technology such as LCD, LED, or OLED panels, as is well-known, or new display technology that may become available. As shown in hidden line, the display panel 405 is octagonal in shape to ensure the display is properly aligned and oriented with respect to the display housing and the orientation of the housing with respect to the tank or other structure it is connected to.

The display portion 404 is divided into display sections for indicating various conditions of the tank 28 (FIG. 1), including a first exemplary display section 414 that shows the level and/or volume of the tank as a temperature-compensated percentage where 0% is an empty tank condition and 100% is a full tank condition. The first display section 414 can additionally and/or alternatively display remaining gallons (or liters) of liquid within the tank, the volume of a gaseous phase of the liquid or the vapor content of the tank above the liquid, which is important for pressurized fuels in both liquid and gaseous states such as propane, natural gas, and so on, as well as other information relating to the contents of the tank and/or conditions within the tank. The display of different information may be controlled in the first section 414 by scroll buttons (not shown), the provision of a touch-sensitive display for the first display portion 404 where swiping actions by the user will scroll to different images representing the tank information, as well as control of the display portion 404 remotely via a smart device, as well as other techniques, hardware, and software methods for sequentially displaying different information. Further details with respect to exemplary information and instructions on an interactive display associated with a smart device will be described with respect to FIGS. 17A through 17F.

The first display portion 404 also includes a second exemplary display section 416 that shows the specific gravity of the liquid within the tank and a third display section 418 showing temperature of the liquid in the tank selectively in Fahrenheit and Celsius, and can additionally or alternatively display the temperature of the gaseous phase within the tank, the outside ambient temperature, tank pressure, outside ambient pressure, and so on, again through sequential scrolling techniques as discussed above. A fourth exemplary display section 420 and fifth exemplary display section 422 include a first alarm indicator 424 and a second alarm indicator 426, respectively, which may comprise one or more back-lit panels with illuminated“ALARM 1” and/or“ALARM 2” or other phraseology when certain conditions have or are occurring that may be of concern to a user. For example, such conditions can include excessively high or low levels of liquid in the tank, tank pressure that drops below a low threshold or exceeds a high threshold, and so on. Other alarm indicators can also or alternatively be used for indicating that fill or distribution valves are not fully closed or open, or that the vehicle is improperly parked (with the vehicle in neutral or without the emergency brake set for example), as well as other conditions that might be of concern to a user. Such conditions can be more fully displayed in the first and/or second display sections, or other display sections (not shown) for indicating such conditions can be implemented.

A sixth display section 428 can be used for permanently or temporarily displaying a company name, advertisements, instructions and warnings, and so on. The sixth display section can be made by placing or adhering a printed adhesive label on the transparent lens (not shown) or other substrate, and/or by silk-screening such information onto the lens or other substrate. To that end, additional LED’s 146 can be provided behind the lens 64 within the seventh display section 144 for back-lighting the printed matter of the seventh display section 144. It will be understood that more or less display sections can be used and that more or less information can be displayed without departing from the spirit and scope of the invention.

The second display portion 406 preferably comprises a series of rectangular bars or segments 430 arranged in an arcuate pattern just inside the circular window 415 of the bezel 41 1 . Each segment can be individually illuminated to reflect a predetermined percent of temperature-compensated volume of liquid in the tank. A scale 432 extends along the length of the bargraph display sections for indicating the percent volume by observing the number of LED segments 158 that are illuminated next to the scale 432. As shown, the cross-hatching of the segments up to about 50% represent a green color, meaning that the contents of the tank are at an acceptable volume or level, and that the liquid volume is approximately 50% of the tank volume. Since liquid expands with increase in temperature, it is standard practice to fill the tank to a level below completely full to allow for expansion of liquid. The scale 432 of the invention, together with the alarm sections 424, 426 of the first display portion 404, ensure that a user is aware of the tank 28 (FIG. 1) being too empty or too full, so appropriate action can be taken.

It will be understood that the bar-shaped segments can be provided in any shape or

configuration. It will be further understood that the colors of the illuminated segments are not limited to green, but can emit light at any frequency within the visual range of the electromagnetic spectrum without departing from the spirit and scope of the invention.

With reference now to FIGS. 17A through 17H, an exemplary simplified series of display screens associated with application specific software program (app) loaded onto the smart device 46 (FIGS. 1 and 8) are illustrated. As previously described, the smart device 46 can be remotely connected to the electronic gauge assembly 12, 400 via Bluetooth or other wireless connection technology for receiving information from the electronic gauge assembly and transmitting information thereto to thereby monitor one or more tanks, as well as controlling the information to be displayed on the or each tank. As shown in FIG. 17A, the user is introduced to a splash screen 440 when the app is first initiated to inform the user of the program that has been accessed on the smart device. The splash screen 440 can include information such as the company name and logo, company contact information, app developer information, the version of the app, and so on. In FIG. 17B, the user is presented with a login screen 442 that prompts the user to enter the user name and password associated with an account previously set up in the app to access private information associated with the account. The user may also be prompted to open a new account if one has not been previously set up, or to give instructions on retrieving the user name or resetting the password. In FIG. 17C, once logged in, the user is presented with a menu screen 444 having a selection of different options such a home screen button 446, a dial selection button 448 for accessing a dial screen 450 having information boxes 452 listing one or more dials previously entered by the user representing one or more electronic gauge assemblies. A selection button 454 is also provided for entering new dial information representing a new electronic gauge assembly.

The menu screen 444 (FIG. 17C) also includes a new dial button 456 for directly entering new dial information without the need to access the screen 450. A temperature sensor button 458 brings the user to an output screen 460 (FIG. 17H) showing information related to liquid temperature associated with a particular dial, the previously user-defined specific gravity for a particular liquid being stored or transported in a particular tank, uncompensated and temperature-compensated liquid volume based on the specific gravity and liquid level measurement, and the percent of liquid remaining in the tank, as well as alarm conditions that may have been activated as previously described. User ID and a particular tank ID can also be displayed on screen 460.

The menu screen 444 (FIG. 17C) also includes an alarm set point button 462 brings the user to an alarm set point screen 465 for setting the Alarml on line 467 representative of percent volume of liquid in the tank or selecting the default Alarml setting, and for setting the Alarm2 on line 469 representative of percent volume of liquid in the tank or selecting the default Alarm2 setting.

The selection of button 464 calls up a specific gravity set-up screen 466 (FIG. 17F) with user- selectable liquid radial buttons 468 reflective of the liquid and its predetermined specific gravity associated with the particular tank configuration being setup or modified. A user-defined radial button 470 can also be selected for entering a liquid not listed along with its specific gravity at line 472, and optionally other information about the liquid. As shown in FIG. 17F, common liquids being stored under high pressure and cryogenic conditions include, but are not limited to, LPG, ISO Butane, N. Butane, NH ₃ , and so on.

An output signal button 474 in FIG. 17C brings the user to an output signal screen 476 (FIG.

17G) for confirming the default low set point 478 or entering a new set point on line 480 reflective of liquid level below an acceptable level in the tank as represented by a particular percent volume in the tank (default set point at 5% for example), with a low current-driven output signal at 4.00 mA for example, as well as the default set point (at 95% for example) 482 or new set point entered at line 484 reflective of liquid above an acceptable level in the tank, as represented by a particular percent volume in the tank, with a high current-driven output signal at 20.00 mA for example.

An app settings button 486 in FIG. 17C brings the user to a settings screen (not shown) to change the units, screen order, background and foreground colors or color schemes, the height or size of the selection buttons or input lines, the default lettering size and style, and so on. Likewise, a“help” button 488 and“about” button 490 calls up help and app information screens, respectively (not shown).

It will be understood that the term "preferably" as used throughout the specification refers to one or more exemplary embodiments of the invention and therefore is not to be interpreted in any limiting sense.

It will be further understood that the term "connect" and its derivatives refer to two or more parts capable of being attached together either directly or indirectly through one or more intermediate members. In addition, terms of orientation and/or position as may be used throughout the specification denote relative, rather than absolute orientations and/or positions.

It will be appreciated by those skilled in the art that changes could be made to the embodiments described above without departing from the broad inventive concept thereof. It will be understood, therefore, that this invention is not limited to the particular embodiments disclosed, but is intended to cover modifications within the spirit and scope of the present invention as defined by the appended claims.