The present disclosure relates to ullage float assemblies and methods that facilitate the refilling and ventilation of fuel tanks, and in particular, fuel tanks used in marine applications.
The present disclosure relates generally to fuel tanks, and more particularly to fuel tanks installed in watercraft, such as ships, yachts, boats, personal watercraft (PWC, e.g., JETSKI® and SEADOO®). More specifically, the disclosure relates to assemblies for and methods of controlling spillage of fuel and ventilation of vapors from fuel tanks, and in particular, watercraft fuel tanks.
Due to environmental concerns, boat fuel tanks are federally regulated and are required eliminate the propensity for raw fuel or vapor from exiting the fuel tank and fuel system into to a waterway (i.e., river, lake, stream, ocean, etc.) and the atmosphere. An Environmental Protection Agency (EPA) regulation requires a controlled filling process to prevent “spitting back” raw fuel into the vessel or into the waterway. Accordingly, boat operators and personnel who fill watercraft fuel tanks must be able to fill the fuel tank without fuel “spitting back” from the tank or spilling.
The marine industry adopted automotive (cars and trucks) technology, and a typical assembly includes a Fluid Limit Vent Valve (FLVV) installed on the tank, and a flapper style check valve installed on the fuel inlet hose just above the tank. During filling, as fuel rushes into the tank, air that is displaced runs out through the FLVV. When the fuel reaches the maximum fill level, the FLVV closes, shutting off airflow. At this point, the fuel backs up the fill hose and trips the aspirator on the nozzle to shutoff. The check valve prevents fuel in the tank from backing up the fill hose, onto the vessel, or into the waterway. Spitback is prevented by designing the assembly to maintain an expansion or ullage space within a fuel tank. The space required for gasoline expansion at elevated temperatures is at or about 5% by volume for the tank.
Unlike automotive fuel tanks, which have a more finite number of sizes, shapes and mounting configurations, watercraft fuel tank have a much wider variety of sizes and shapes along with how and where a fuel tank is mounted on the watercraft. In addition, recreational watercraft experience angular attitudes during in water refueling, boating activities, adverse weather conditions and storage. Existing fuel tank ullage assemblies utilize floating balls or captured floats in tube or a cylindrical cage that rely on the placement of the ullage float valve seats to determine ullage space in a fuel tank, however, these existing assemblies are limited to certain fuel tank configurations, smaller relative capacities and are primarily rectangular in configuration. Because of these factors, a much greater number of ullage float assembly sizes and configurations are required for watercraft compared to automotive ullage float assemblies.
Accordingly, there is a need for ullage float assemblies and methods that can be readily adapted for all watercraft fuel tank configurations and addresses all refueling, in-use fuel and vapor management considerations.
One or more embodiments of the disclosure are directed to a fuel assembly ullage float assembly comprising a guide member having a first end and a second end, where at least the first end has a retaining element; a valve body including a first valve port and a second valve port in fluid communication and defining an inner sidewall and an outer sidewall, the second valve port including a flared receptacle and a valve seat, the flared receptacle including a diameter that decreases from a lower portion of the flared receptacle to the valve seat, the second end of the guide member mounted to the valve body; and an ullage float slidably mounted on the guide member between the retaining element and the valve seat, the ullage float having a height H and a stepped outside surface including an upper portion having a diameter D1 and a lower portion having a diameter that is greater than the diameter D1, the ullage float including a sealing ledge that is configured to seal against the valve seat.
A second embodiment of the of the disclosure are directed to an ullage float assembly comprising a guide member having a first end and a second end, where the first end has a retaining element; a valve body including a first valve port in fluid communication with at least one of incoming air, exiting air, fuel, fuel vapor and incoming fuel and a second valve port in fluid communication and defining an inner sidewall and an outer sidewall, the second valve port including a receptacle and a valve seat, the second end of the guide member mounted to the valve body; and an ullage float slidably mounted on the guide member between the retaining element and the valve seat, the ullage float comprising an elastomeric foam body having a height H and an outside surface configured to seal against the valve seat.
A second aspect of the disclosure pertains to a method of preventing spillage of fuel from a fuel tank during a refueling and a diurnal fuel volumetric expansion event. A method comprising mounting an ullage fuel float valve to a wall, for example, an upper or top wall, of a fuel tank, the ullage fuel float valve comprising a fuel inlet port and a fuel outlet port in fluid communication and a slidably mounted ullage fuel float configured to rise as fuel is added to the fuel tank and fall as fuel exits the fuel tank; mounting an ullage vent float valve to a wall, for example, an upper or top wall, of a fuel tank, the ullage vent float valve comprising an ullage vent port and an air inlet port in fluid communication and an ullage vent float configured to rise as diurnally heated volumetric expansion occurs or as fuel is added to the fuel tank and fall as fuel diurnally shrinks or exits the fuel tank; and filling the fuel tank with a refueling nozzle, and when the fuel tank reaches a predetermined fill level, the ullage vent float terminates flow of vapor through the ullage vent port and backpressure generated in the fuel tank, drives incoming raw fuel back up the up the fuel inlet port and refueling nozzle, shuts off the refueling nozzle and prevents spillage of fuel from a fuel tank.
Before describing several exemplary embodiments of the disclosure, it is to be understood that the disclosure is not limited to the details of construction or process steps set forth in the following description. The disclosure is capable of other embodiments and of being practiced or being carried out in various ways.
With respect to terms used in this disclosure, the following definitions are provided.
As used herein, the use of “a,” “an,” and “the” includes the singular and plural.
Embodiments of the disclosure provide ullage float assemblies and methods that are configured to initiate a refueling shut off event and substantially reduce and/or eliminate spit-back from a wide variety of watercraft fuel tanks as required by EPA regulations. Embodiments of the disclosure provide disclosure provide ullage float assemblies and methods that facilitate the refilling and proper ventilation of a fuel tank. One or more embodiments of ullage float assemblies and methods provide one or more of the following features: simple in design, easy to manufacture, reliable, low cost, resistant to fuel permeation and safer for the environment than existing assemblies and methods. Embodiments of the ullage float assemblies and methods also eliminate an enclosure or cage that is used in existing assembly to enclose or surround the float, which render existing assemblies unduly complex and require a check valve.
A first aspect of the disclosure pertains to an ullage float assembly 100 for a fuel system, for example a marine watercraft fuel system. In one embodiment with reference to
The ullage float assembly 100 further comprises a valve body 120 including a first valve port 122 and a second valve port 124 in fluid communication and defining an inner sidewall 126 and an outer sidewall 128. In the embodiment shown, the first valve port 122 and the second valve port 124 are at a right angle (90 degree angle) to each other, but this configuration is nonlimiting. In some embodiments, the first valve port 122 and the second valve port 124 are at angles that are not at a 90 degree angle to each other. The first valve port 122 includes a flared receptacle 130 and a valve seat 132, the flared receptacle 130 including a diameter Df that decreases from a lower section 134 of the flared receptacle 130 to the valve seat 132. The second end 106 of the guide member 102 is mounted to the valve body 120. The second end 106 can be mounted by a threaded connection, a compression fitting or any other suitable connection. The valve body 120 further comprises a flange 107 that extends from the valve body and a gasket 105 is sandwiched between the valve body and a wall 103 of a fuel tank 101. It will be appreciated that only a portion of the wall 103 of the fuel tank 101 is shown, namely an upper or top wall as shown.
The ullage float assembly 100 further comprises an ullage float 150 slidably mounted on the guide member 102 between the retaining element 108 and the valve seat 132, the ullage float 150 having a height H and a stepped outside surface 152 including an upper portion 154 having a diameter D1 and a lower portion 158 having a diameter that is greater than the diameter D1, the ullage float 150 including a sealing ledge 160 that is configured to seal against the valve seat 132. It will be appreciated that diameter D1 is less than the diameter Df of the lower section 134 of the flared opening 134.
In one or more embodiments of the disclosure, the ullage float 150 further includes an intermediate portion 156 disposed between the lower portion 158 and the upper portion 154, the intermediate portion 156 having a diameter D2 and the lower portion 158 having a diameter D3 such that D3 is greater than D2 and D2 is greater than D1 and the sealing ledge 160 is located at a transition surface 164 from the intermediate portion 156 and the upper portion 154. In some embodiments, the diameter D2 is less than the diameter Df of the lower section 134 of the flared opening 134.
In one or more embodiments of the disclosure, the intermediate portion 156 of the ullage float 150 valve is configured to fit within the flared receptacle 130 of the valve body 120 and to contact the valve seat 132 in the valve body 120 at the second valve port 124. The upper portion 154 is configured to fit within the inner sidewall 126 of the valve body 120 at the second valve port 124. The lower portion 158 facilitates motion of ullage float 150 to moveably slide along the guide member 102.
In one or more embodiments of the disclosure, the ullage float 150 assembly 100 further includes a float gasket 166 disposed around the upper portion 154 of the ullage float 150 and seated on a transition surface 164 from the intermediate portion 156 of the ullage float 150 to the upper portion 154, the float gasket 166 configured to form a fluid seal between the ullage float 150 with the valve seat 132 to terminate fluid communication between the first valve port 122 and the second valve port 124 when the ullage float 150 is pushed against the valve seat 132 when the fuel tank 101 is at a predetermined level during fueling or a diurnal fuel volumetric expansion event to prevent fuel spillage. In some embodiments of the disclosure, the upper portion 154 of the ullage float 150 has a groove 168 adjacent to the intermediate portion 156 to provide the float gasket 166 with an interference fit to hold the float gasket 166 on the ullage float 150 and to prevent the float gasket 166 from inadvertently sliding off the ullage float 150. In some embodiments of the disclosure, the upper portion 154 also includes a rounded edge 170 to promote smooth engagement of upper portion 154 of ullage float 150 fitting within inner sidewall 126. Rounded edge 170 of upper portion 154 also provides convenient installation of a replacement float gasket 166 to be fitted into the groove 168 upon such event.
In one or more embodiments of the disclosure, ullage float 150 is comprised of a fuel-resistant and non-swelling material selected from an elastomer and a rubber. In another aspect of the embodiment, the fuel-resistant and non-swelling material is selected from the group consisting of a nitrile butadiene and a fluoropolymer elastomer. In another aspect of the embodiment, the fuel-resistant and non-swelling material is selected from the group consisting of a gas-filled nitrile butadiene and a gas-filled fluoropolymer elastomer.
In an exemplary embodiment of the disclosure, the fuel-resistant and non-swelling material is selected from the group consisting of a gas-filled, closed pore nitrile butadiene and a gas-filled closed pore fluoropolymer elastomer. Combined with the dimensions of the lower float of ullage float 150, the gas-filled closed pore fluoropolymer elastomer provides sufficient buoyancy with fuel to exert a force on the ullage float 150 great enough to slidably move ullage float 150 along guide member 102 and push against the valve seat 132 on the valve body 120 to terminate fluid communication between the first valve port 122 and second valve port 124. Appropriate fluoropolymer elastomer material that can be used for the ullage float 150 includes Viton®, available from E.I. du Pont de Nemours & Company, or other equivalents with similar properties of fluoropolymer elastomer materials.
In some embodiments of the disclosure, the upper portion 154, intermediate portion 156, and lower portion 158 of the ullage float 150 may be slightly tapered to improve flow of fuel when passing through the ullage float 150 valve assembly and into the fuel tank 199 or to better engage with the flared receptacle 130 of the valve body 120.
In other embodiments of the disclosure, the ullage float 150 is configured to movably slide along the guide member 102 when an amount of fuel causes floatation lift of the guide member 102 in the fuel tank 199. The ullage float 150 gets lifted upwards towards the second end 106 of the guide member 102 as the fuel fill line 195 increases within in a fuel tank 199. Alternatively, the ullage float 150 moves downwards towards the first end 104 of the guide member 102 when the fuel fill line 195 in a fuel tank 199 decreases.
In one or more embodiments of the disclosure the guide member 102 comprises a rod, and the ullage float 150 comprises a track 172 configured to permit the ullage float 150 to move along the guide member 102. The track 172 can comprise a central opening running along a length of the ullage float, sized and shaped to allow the ullage float 150 to freely slide on the guide member 102. In one or more embodiments of the disclosure, the second end 106 of the guide member 102 is mounted to the valve body 120 for assembly and to reduce sway in the guide member 102. In an exemplary embodiment of the disclosure, the guide member 102 is welded to the inner sidewall 126 of the valve body 120. In another embodiment of the disclosure, the first end 104 of the guide element can be threaded to mechanically fasten to the inner sidewall 126 of valve body 120. In one or more embodiments of the disclosure, the guide member is parallel with the first valve port 122 to facilitate engagement between the sealing ledge 160 of the ullage float 150 to the valve seat 132 within the first valve port 122.
In another embodiment of the disclosure, the guide member 102 comprises of a fuel-resistant and non-corrosive material. In one or more embodiments of the disclosure, the material of the guide member 102 is selected from a group that includes but is not limited to: aluminum and aluminum alloys, copper and copper alloys, titanium and titanium alloys, nickel alloys, Iron, steel, stainless steels and other metals with appropriate fuel-resistance and non-corrosive properties widely used in the marine industry.
In one or more embodiments of the disclosure, a retaining element 108 on the first end 104 of the guide member 102, the retaining element 108 configured to hold the ullage float 150 on the guide member 102. In other embodiments of the disclosure, the retaining element 108 can include a retaining ring, E-Clips, push nut, threaded nut, a washer, or similar retaining devices. In some embodiments of the disclosure, the second end 106 of the guide element can be threaded to receive a threaded nut to use as a retaining element 108. In other embodiments of the disclosure, the second end 106 of the guide element can have a slot (not shown) to receive retaining rings, E-clips, or push nuts. In another embodiment of the disclosure, any object sufficient to reliably attach to the first end 104 of the guide member 102 and hold the ullage float 150 on the guide can be utilized as a retaining element 108.
A second embodiment of the disclosure pertains to an ullage float assembly 100 for a fuel system. In one embodiment with reference to
The ullage float assembly 100 further comprises a valve body 120 including a first valve port 122 in fluid communication with at least one of incoming air, exiting air, fuel, fuel vapor and incoming fuel and a second valve port 124 in fluid communication and defining an inner sidewall 126 and an outer sidewall 128, the second valve port 124 including a receptacle 130 and a valve seat 132, the second end 106 of the guide member 102 mounted to the valve body 120; and
The ullage float assembly 100 further comprises an ullage float 150 slidably mounted on the guide member 102 between the retaining element 108 and the valve seat 132, the ullage float 150 comprising an elastomeric foam body having a height H and an outside surface configured to seal against the valve seat 132. In one or more embodiments of the disclosure, the ullage fuel float comprises a gas-filled, closed cell butadiene.
In one or more embodiments of the disclosure, the receptacle 130 comprises flared receptacle 130 including a diameter that decreases from a lower section 134 of the flared receptacle 130 to the valve seat 132 and the outside surface of the ullage float 150 including a stepped surface including an upper portion 154 having a diameter D1 and a lower portion 158 having a diameter that is greater than the diameter D1, the ullage float 150 including a sealing ledge 160 that is configured to seal against the valve seat 132, the ullage float assembly 100 configured to prevent spillage of fuel from a fuel tank 199 during fueling or a diurnal fuel volumetric expansion event.
Referring now to
Referring now to
The ullage vent valve 220 is mounted to a wall, in particular, an upper wall or the top wall 297 of the fuel tank 299 with a second gasket 207 between the top wall 297 and a flange 209 of the ullage vent valve 220. The ullage vent valve 220 comprises an air outlet port 222 and an air inlet port 224 in fluid communication and an ullage vent float 226 slidably mounted to a second guide member 204. The ullage vent float 226 is configured to rise as diurnally heated volumetric expansion occurs or as incoming fuel 288 is added to the fuel tank 299 causing the tank fuel 290 level to rise and fall as the tank fuel 290 diurnally reduces in volume or exits the fuel tank 299 during use of fuel to power an engine.
In use, during filling of the fuel tank 299 with a refueling nozzle 289 as shown in
The closure of the ullage fuel valve 210 due to the backpressure generated in the fuel tank 299 causes incoming fuel 288 to fill up the fill hose line 286 and cause shut off the refueling nozzle to prevent spillage of the tank fuel 290 from the fuel tank 299. In one or more embodiments, the ullage fuel float 216 having a configuration similar to the ullage float 150 shown in
In an embodiment of the disclosure, terminating flow of vapor through the ullage vent valve 220 occurs prior to the closure of the ullage fuel valve 210 which is caused by backpressure generated in the fuel tank 299. This drives incoming fuel 288 upward in the fill hose line 286 to causes refueling liquid fuel to actuate common aspirator valve (not shown) of the refueling nozzle, which is the typical shut off operation of the refueling event.
In one or more embodiments of the disclosure, the fuel outlet port 214 includes a flared receptacle 230 and the ullage valve seat 232, the flared receptacle 230 including a diameter that decreases from a lower portion 234 of the flared receptacle 230 to the ullage valve seat 232, similar to the configuration of the valve body shown in
In one or more embodiments of the disclosure, the air inlet port 224 includes a flared receptacle 228 and the vent valve seat 233, the flared receptacle 228 including a diameter that decreases from a lower portion 235 of the flared receptacle 228 to the vent valve seat 233, similar to the configuration of the valve body shown in
In one or more embodiments of the disclosure, the geometry of the fuel tank 299 and the fuel tank volume is used to determine the height H2. In an exemplary embodiment of the disclosure, fuel float height H1 is greater than vent float height H2 to enhance backpressure functionality and facilitate shut off operation of fuel nozzle and prevent spit-back from occurring. The configuration or overall geometry of ullage fuel float 216 is the same or similar to the ullage vent float 226 as shown in
In one or more embodiments, the respective heights of the vent float H2 and fuel float H1 are determined by the volume and geometry of a fuel tank 299. In an exemplary embodiment of the disclosure, the respective heights of the vent float H2 and fuel float H1 can be adjusted along with assembly clearances to attenuate and dissipate backpressure to achieve a desired vapor/ullage space after a non-spit back refueling event.
In one or more embodiments of the disclosure, the ullage valve seat 232 of the ullage fuel valve 210 and the vent valve seat 233 of the ullage vent valve 220 are at the same level with respect to each other, located at the uppermost practical level of the fuel tank 299. This is to ease method of manufacturing of ullage fuel system 200 and simplify installation of ullage fuel system on a fuel tank 299. The flange 203 of the ullage fuel valve 210 and the flange 209 are of the same diameter to secure the ullage fuel system 200 to a top wall 297 of a fuel tank 299.
In a more specific embodiment of the disclosure, the height H2 of the ullage vent float is calculated by obtaining the total volume of the fuel tank 299. The total volume is then multiplied by 95% to find the predetermined level 292 within the fuel tank 299. The length between the top wall 297 and the predetermined level 292 is used as the height H2 of the ullage vent float 226. Subsequently, the height H1 of the ullage fuel float 216 is determined by adding 0.5″ to 2.0″ to the height of H2. The additional height H2 of the ullage fuel float can vary depending on the geometry of the fuel tank 299.
In one or more embodiments of the disclosure, the fuel tank 299 has a fuel volume and shutting off the refueling occurs when the fuel tank 299 is filled to 95% of the fuel tank 299 volume, which is when the tank fuel 290 reaches the predetermined level 292.
In one or more embodiments of the disclosure, the ullage vent valve 220 may include an additional port as shown in
In one or more embodiments of the disclosure, the ullage vent valve 220 may include an air outlet port 222 that is smaller in diameter than the fuel inlet port 212 on the ullage fuel valve 210 as shown in
Although the disclosure herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present disclosure. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present disclosure as disclosed.
This application claims priority to U.S. Provisional Application No. 63/211,137, filed Jun. 16, 2021, the entire disclosures of which are hereby incorporated by reference herein.
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