The present invention relates generally to fuel dispensing systems for delivering fuels of a desired octane rating, the fuel being either a single fuel product of a given octane level or a blend of two or more fuel products of varying octane levels.
Numerous dispensing systems exist for blending two or more fuels during a fuel dispensing event. Such systems are used quite often in a service station environment where it is desired to dispense a plurality of different grades or octane levels of fuel products by blending at least a high octane level product with a low octane level product to create one or more mid-level octane products. Blending systems offer the potential for savings stemming from reduced storage capacity requirements both at the service station and the bulk plant level. Such systems are also used for blending diesel fuels of varying cetane content levels, gasoline/ethanol fuels of varying ethanol content levels, and diesel/biodiesel blends of varying biodiesel content levels.
Often, these dispensing systems are based on an important underlying assumption, that the octane levels (or octane, ethanol, biodiesel levels) of the fuel products in the low and high octane fuel storage tanks, or more where present, are correct. For example, it is assumed that the low octane blend component has an octane of about 86 to 87 and that the high octane component has an octane level of about 92 to 93. However, due to various issues noted below, the actual octane levels of the fuel products may differ from what is expected.
A potential problem with many fuel blending systems is that they have no provision to detect the delivery of an incorrect octane level product in either the high or low level octane blending component storage tanks. Specifically, if the low octane product and/or high octane product are of different octane levels than the assumed octane rating, it may not be possible to deliver a proper octane blend during fueling operations.
Existing fuel dispensing systems are often prone to inaccuracy issues with respect to octane blend accuracy for small transaction dispensing events. Those inaccuracies can be due to a volume of blended fuel from the previous dispensing event being maintained in the fuel hose, the volume being defined between the blend manifold and fuel nozzle, which is the dispensed on the subsequent fueling event. This is typically only an issue where the octane ratings of the fuels for the two fueling events differ from each other. For example, where the selected octane ratings are the same for both events, the actual octane level of the retained volume from the first event should match the desired octane level selected by the operator for the fuel of the second event. However, where an octane level of the fuel dispensed in the previous fueling event is lower than the desired octane rating of the fuel dispensed in the subsequent fueling event, the lower octane level of the retained volume from the first fueling event causes the octane level of the overall volume of the fuel delivered in the second fueling event to be less than desired.
The present disclosure recognizes and addresses the foregoing considerations, and others, of prior art constructions and methods.
An embodiment of the present invention provides a method of delivering a selected fuel product having a selected octane level to an operator from a fuel dispenser including a blend manifold, a fuel nozzle, and a fuel hose extending therebetween. The method comprises the steps of determining a first volume of a first fuel that is retained in the fuel hose upon completion of a first fueling event, determining a first octane level of the first volume of the first fuel, determining a second volume of a second fuel having a second octane level, and delivering the first fuel volume and the second fuel volume to the operator during a second fueling event, wherein a total volume of fuel equaling the first volume of the first fuel and the second volume of the second fuel has a total octane level that falls within a predetermined limit of the selected octane level of the selected fuel product.
An alternate embodiment of the present invention provides a fuel dispensing installation which includes a first fuel tank containing a first fuel having a first parameter at a first level, second fuel tank containing a second fuel having the first parameter at a second level, a plurality of conduits connecting the first and second tanks to a fuel dispenser, said fuel dispenser having a blending system for blending the first and second fuels to form at least a first fuel blend having a third level of the first parameter, and a first and a second sensor operatively connected to the fuel dispenser so as to be in fluid communication with the first and second fuels, respectively, so as to sense the first level and the second level of the first parameter of the first and second fuels, respectively, and to output signals representative of the first level and the second level of the first parameter of the first and second fuels to the blending system, wherein the blending system receives the sensor output signals and generates output control signals to maintain the first parameter level of the first fuel blend within a predetermined range of the third level of the first parameter.
Another alternate embodiment of the present invention provides a method of delivering a selected fuel product having a selected level of a first parameter to an operator from a fuel dispenser including a blend manifold, a fuel nozzle, and a fuel hose extending therebetween, the method including the steps of determining a first volume of a first fuel that is retained in the fuel hose upon completion of a first fueling event, determining a first level of the first parameter of the first volume of the first fuel, determining a second volume of a second fuel having a second level of the first parameter, and delivering the first fuel volume and the second fuel volume to the operator during a second fueling event, wherein a total volume equaling the first volume of the first fuel and the second volume of the second fuel has a total level of the first parameter that falls within a predetermined limit of the selected level of the first parameter of the selected fuel product.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate one or more embodiments of the invention and, together with the description, serve to explain the principles of the invention.
A full and enabling disclosure of the present invention, including the best mode thereof to one of ordinary skill in the art, is set forth more particularly in the remainder of the specification, which makes reference to the accompanying figures, in which:
Repeat use of reference characters in the present specification and drawings is intended to represent same or analogous features or elements of the invention.
Reference will now be made in detail to presently preferred embodiments of the invention, one or more examples of which are illustrated in the accompanying drawings. Each example is provided by way of explanation, not limitation, of the invention. In fact, it will be apparent to those skilled in the art that modifications and variations can be made in the present invention without departing from the scope and spirit thereof. For instance, features illustrated or described as part of one embodiment may be used on another embodiment to yield a still further embodiment. Thus, it is intended that the present invention covers such modifications and variations as come within the scope of the appended claims and their equivalents.
An embodiment of a fuel dispenser 300 in accordance with the present invention is shown in
Fuel dispenser 300 is in fluid communication with product sources 100,200 via supply lines 101,201 and includes a customer display 351, an octane level display 352 and product blend selectors 353 for customer use to select the blended product desired for a particular transaction. The other components of fuel dispenser 300 include first and second real time octane sensors 310,312 for providing signals 314,316 indicative of the octane level of first and second products respectively. Note, in alternate embodiments, the octane sensors may be replaced by sensors for detecting cetane, ethanol, biodiesel content, etc., dependent upon the type of fuel being dispensed. First and second flow control valves 306,308 downstream of octane sensors 310,312 control the flow rate of first and second products, respectively. First and second flow meters 302,304 connected to flow control valves 306,308 provide electronic signals 322,332 to dispenser electronics 350 indicative of the flow rate of a first and second products, respectively. Product flow lines 324,334 provide paths for delivery of each of the first and second products to blend manifold 340 and then to nozzle 10. As is well known in the art, nozzle 10 is connected to dispenser 300 via a flexible hose. First and second flow control valves 306,308 are controlled by dispenser electronics 350 via signal lines 320,330 respectively. Various other components such as fuel filters, check valves, solenoids and the like may also be provided as necessary.
An alternative embodiment of a fuel dispenser according to the present invention is shown in
Either system described within
The term “real time octane sensor” as used herein means an octane sensing device capable of determining the octane level and transmitting a signal indicative of the octane level of a gasoline fluid to a dispenser controller or to some other device. The sensor must be capable of performing this function fast enough to enable the dispenser controller to correct a blending process continuously within the time span of a typical retail transaction. The scope of the present invention includes the use of currently known octane sensors and those that may be developed in the future so long as they meet this performance requirement.
The flow charts shown in
Referring now to
If test 26 answers no, then the routine proceeds to test 28 where (OB) is again compared to (OS) to determine whether (OB) is greater than (OS). If this test answers yes, then the routine proceeds to 29 where flow control valves 306,308 are controlled to either reduce the amount of high octane blended component (HI) or increase the amount of low octane blending component (LO) making up the blended product. Either action may be used singly or in combination to correct the octane level (OB) of the blended product. If test 28 answers no, then the routine proceeds to 25 where flow control valves 306,308 are controlled to increase the amount of high octane blending component (HI) and/or reduce the amount of low octane blending component (LO) being supplied.
An alternative embodiment is described in the flow chart shown in
If the result of test 46 is yes, then the routine proceeds to test 48 where it is determined whether the value of (OB) exceeds the value of (OS) by a predetermined amount. If this test answers yes, then the routine proceeds to block 49 as described above. If this test answers no, then the routine proceeds to block 45 which permits the fuel delivery to continue but updates the octane display for the customer to show that an octane level higher than that selected is being provided. The system could also incorporate memory provided to record all occurrences of a higher octane product being dispensed than was actually selected. A record of such occurrences can be used by regulatory authorities to monitor blending performance and also may be used by operators to make appropriate adjustments.
Referring now to the flow chart shown in
At test 56, (OH) is compared to (OS). If the two values are equal, then the routine proceeds to step 57 where flow control valves 306, 308 are set to the positions which correspond to octane level (OS), and the fuel dispensing event is initiated. In short, where the octane level of the fuel selected for the present event (OS) is the same as the octane level of the fuel delivered during the preceding event, and therefore the same octane level (OH) of the retrieved volume (VH), there is no need to compensate for the portion of fuel that remained in the fuel hose (VH) after the preceding event.
If test 56 answers no, then the routine proceeds to test 58 where dispenser electronics 350 determine a compensating volume (VC) of fuel having an octane level (OC) dependent upon whether (OH) is greater than or less than (OS). If (OH) is greater than (OS), octane level (OC) of compensating volume (VC), as determined by dispenser electronics 350, will necessarily be a lower octane level than (OH). (VC) and (OC) may both vary, but are selected such that the combination of volumes of (VC) having an octane level (OC) with retained volume (VH) will result in a total volume of fuel (VT) that has an octane level substantially equal to the octane level (OS) selected by the operator. Optionally, the value of (VC) may be provided to the operator via display 351 to help insure that the operator dispenses enough fuel during the transaction to allow the selected (OS) to be attained. After (VC) and (OC) are determined, the routine proceeds to step 61 where the dispensing of fuel is initiated, with volumes (VH) and (VC) being delivered prior to the remainder of the desired volume of fuel being delivered at the selected octane level (OS), in accordance with the methods previously discussed with regard to
If, on the other hand, test 56 determines that (OH) is less than (OS), octane level (OC) of compensating volume (VC), as determined by dispenser electronics 350, will necessarily be a higher octane level than (OH). Again, (VC) and (OC) may both vary, but are selected such that the combination of volumes of (VC) having an octane level (OC) with retained volume (VH) will result in a total volume of fuel (VT) that has an octane level substantially equal to the octane level (OS) selected by the operator. As discussed above, after (VC) and (OC) are determined, the routine proceeds to step 61 where the dispensing of fuel is initiated, with volumes (VH) and (VC) being delivered prior to the remainder of the desired volume of fuel being delivered at the selected octane level (OS), in accordance with the methods previously discussed with regard to
As alluded to above, equipment malfunctions such as internal meter leakage, meter calibration problems, valve failures and piping leaks can cause even a properly functioning prior art blending system to fail to deliver the desired octane level product. Certain aspects of the present invention may be incorporated into existing blending dispenser systems to address these situations. For instance, a blend octane sensor 341 may be provided for comparing the actual octane level of the blend to that selected by the customer. This information may be displayed to the customer during fueling as an assurance that the desired fuel grade is being delivered. If the actual octane level falls below that selected by the customer, dispenser electronics 350 can shut down the fueling operation and notify operating personnel via site controller 400.
It will be readily appreciated that the comparison steps described above encompass comparing a measured octane level not only to a single predetermined value but also to a range of values. Given the measurement error inherent in any instrument, it may be feasible to compare the measured octane value to determine whether it falls within a certain range of values. The scope of the present invention includes making the comparison steps described above using either a single point value or an octane range.
Historical information concerning the octane levels of both blending components and blended products may be stored in dispenser electronics 250, site controller 400 or other storage device for compliance monitoring by weights and measures authorities. These authorities may monitor octane levels from a remote location via a communications link with site controller 400. The advantages of such remote monitoring include reduced costs of compliance inspections and the ability to conduct unannounced monitoring checks on octane levels being delivered to the public.
The various components of the system described above may be combined in a variety of ways depending on the desired performance objectives. For example, if costs are a concern, dispenser 300 may be provided with only the blend octane sensor 341 and not with first and second octane sensors 310,312. The signal from blend octane sensor 341 is used by dispenser electronics 350 along with flow rate information from first and second meters 302,304 to generate output signals to flow control valves 306,308. In this embodiment, sensors on the inlet side of first and second meters 302,304 are not required. Conversely, octane monitoring may be conducted only on the inlet side of first and second meters 302,304 using first and second octane sensors 310,312 without monitoring the blended product. It will be readily apparent to one of ordinary skill in the art that octane level sensing may be incorporated into a dispenser blending process by either: 1) monitoring the octane level of the blended product without regard to the octane level of the incoming blend components or 2) monitoring the octane levels of the blend components without regard to the octane level of the blended product.
While preferred embodiments of the invention have been shown and described, modifications and variations thereto may be practiced by those of ordinary skill in the art without departing from the spirit and scope of the present invention, which is more particularly set forth in the appended claims. Specifically, the embodiments of the invention disclosed herein may be used when blending diesel fuels of varying cetane content levels, gasoline/ethanol fuels of varying ethanol content levels, and diesel/biodiesel blends of varying biodiesel content levels. In addition, it should be understood the aspects of the various embodiments may be interchanged without departing from the scope of the present invention. Furthermore, those of ordinary skill in the art will appreciate that the foregoing description is by way of example only, and is not intended to limit the invention as further described in such appended claims.
This application is a divisional of copending application Ser. No. 15/797,428, filed Oct. 30, 2017, which is a divisional of application Ser. No. 14/713,743, now U.S. Pat. No. 9,802,810, filed May 15, 2015. The aforementioned applications are relied upon and incorporated fully herein by reference for all purposes.
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Number | Date | Country | |
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20210101795 A1 | Apr 2021 | US |
Number | Date | Country | |
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Parent | 15797428 | Oct 2017 | US |
Child | 17124119 | US | |
Parent | 14713743 | May 2015 | US |
Child | 15797428 | US |