The present invention relates generally to the art of fuel dispensing nozzles.
More particularly, it relates to a fuel dispensing nozzle having a hold open mechanism configured to be operated by the same hand as the nozzle's actuation lever.
Fuel dispensing facilities are in widespread use, providing customers with liquid fuel for various applications. A common fueling transaction, where fuel is dispensed into a vehicle fuel tank, typically proceeds as follows: The customer indicates to the fuel dispenser the type of fuel desired and a payment method. The fuel dispenser authorizes payment and allows pressurized fuel to be available for dispensing. The customer places the nozzle into the vehicle fuel tank and pulls the lever of the nozzle to open a valve and dispense the desired amount of fuel.
Fuel dispensing nozzles are often equipped with hold open mechanisms that allow the lever to remain in an open flow position without the need to be continuously grasped by the user. In a typical arrangement, the hold open mechanism includes a latch member which pivotally engages with one of a series of catches in the desired flow position. Oftentimes, the latch member will be located at the distal end of the lever with the catches being located at the back of the hand guard in which the lever is located. When the hold open mechanism is actuated, fuel will continue to flow until the hold open mechanism is manually released or until the vehicle's tank is full causing the nozzle's shutoff mechanism to trip.
While current hold open mechanisms have worked reasonably well, they are not without disadvantages. For example, hold open mechanisms such as the one described above generally require a second hand to actuate. Specifically, because the latch member is located at the distal end of the lever and the user is gripping the lever with one hand (presumably the user's dominant hand), the other hand is required to position or release the latch member relative to the desired catch. In addition, there can be manufacturing variations between the nozzle body, hand guard, and lever which exacerbate tolerance issues between the latch member and the catch. This can cause the hold open mechanism to repeatedly trip at undesired times.
The present invention recognizes the foregoing, and other, considerations of the prior art.
One aspect of the present invention provides a fuel dispensing nozzle comprising a nozzle body defining a dispensing path extending from a distal inlet to a proximal outlet and configured to dispense fuel. A fuel flow valve is disposed in the nozzle body between the distal inlet and the proximal outlet. An actuation assembly movable to open the fuel flow valve is also provided. The nozzle also includes a shut-off mechanism operatively connected to the actuation assembly. A hand lever is pivotally connected with respect to the nozzle body, the hand lever being operatively connected to the actuation assembly so as to cause opening of the fuel flow valve when the hand lever is pivoted in a valve opening direction. The hand lever has a grasping portion extending between a proximal location nearer the proximal outlet and a distal location.
The nozzle according to this aspect further includes a hold open mechanism including a trigger disposed at the proximal location of the hand lever. The trigger is pivotally connected to the hand lever and has an engaging element. A catch member is fixed with respect to the nozzle body and defines a plurality of catches corresponding to respective flow positions. The catches are each configured to receive the engaging element of the trigger.
In exemplary embodiments, the actuation assembly may comprise a dual shaft assembly having a first shaft axially movable with respect to a second shaft. For example, the second shaft may be coaxially mounted in the first shaft and urged apart from the first shaft by an actuation assembly spring. A lesser force due to the actuation assembly spring alone is insufficient to maintain the engaging element of the trigger in the catch.
In exemplary embodiments, the shut-off mechanism may include a piston in fluid communication on one side with a shut-off port defined in the nozzle body. The shut-off mechanism may also carry at least one locking roller forming a releasable locking mechanism between the first shaft and the second shaft.
In exemplary embodiments, the hand lever may be generally L-shaped with a shorter portion and a longer portion substantially perpendicular to each other, the longer portion forming the grasping portion. The trigger may be pivotally connected to the hand lever at a pivot point substantially at an intersection of the shorter portion and the longer portion of the hand lever.
In exemplary embodiments, the hold open mechanism may further include a spring urging the trigger into a free state. In addition, each of the catches of the catch member may be generally U-shaped having a leading side and a trailing side, the leading side being oriented in a direction that is substantially normal to a line extending between the engaging element of the trigger when disposed in the catch and a pivot point at which the trigger is pivotally connected to the hand lever. The catch member may be connected directly to the nozzle body.
In exemplary embodiments, a spring-loaded check valve may be located in the nozzle body. Moreover, a coil spring may be mounted axially with respect to the fuel flow valve to urge the fuel flow valve into a closed position.
Another aspect of the present invention provides a fuel dispensing nozzle comprising a nozzle body defining a dispensing path. A fuel flow valve is disposed in the nozzle body. An actuation assembly movable to open the fuel flow valve is also provided. A hand lever is pivotally connected with respect to the nozzle body, the hand lever being operatively connected to the actuation assembly so as to cause opening of the fuel flow valve when the hand lever is pivoted in a valve opening direction.
The nozzle according to this aspect further includes a hold open mechanism including a trigger pivotally connected to the hand lever and having an engaging element. A catch member is fixed with respect to the nozzle body, the catch member defining a plurality of catches corresponding to respective flow positions, each of the catches configured to receive the engaging element of the trigger. Specifically, each of the catches according to this aspect is generally U-shaped having a leading side and a trailing side, the leading side being oriented in a direction that is substantially normal to a line extending between the engaging element of the trigger when disposed in the catch and a pivot point at which the trigger is pivotally connected to the hand lever.
A still further aspect of the present invention provides a fuel dispensing nozzle comprising a nozzle body defining a dispensing path extending from a distal inlet to a proximal outlet and configured to dispense fuel. A fuel flow valve is disposed in the nozzle body between the distal inlet and proximal outlet. An actuation assembly is movable to open the fuel flow valve, the actuation assembly comprising a dual shaft assembly having a first shaft axially movable with respect to a second shaft, the second shaft being urged apart from the first shaft by an actuation assembly spring, wherein a lesser force due to the actuation assembly spring alone is insufficient to maintain the engaging element of the trigger in the catch.
The nozzle according to this aspect further comprises a hand lever pivotally connected with respect to the nozzle body, the hand lever being operatively connected to the actuation assembly so as to cause opening of the fuel flow valve when the hand lever is pivoted in a valve opening direction. A hold open mechanism is also provided, including a trigger pivotally connected to the hand lever and having an engaging element. A catch member is fixed with respect to the nozzle body, the catch member defining a plurality of catches corresponding to respective flow positions, each of the catches being configured to receive the engaging element of the trigger.
Additional aspects of the present invention are provided by various other combinations and subcombinations of the disclosed elements, as well as methods of practicing same.
A full and enabling disclosure of the present invention, including the best mode thereof directed to one of ordinary skill in the art, is set forth in the specification, which makes reference to the appended drawings, 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 of the invention, 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 or 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.
The distal end 22 of nozzle body 12 defines an inlet 24 (
Referring now to
Trigger 38 is moved by the user, such as by the user's index finger of the same hand that is squeezing lever 36, against the bias of a torsion spring 52 located around pivot point 50. Toward this end, trigger body 48 may include a tab portion 54 at the end opposite the pivot point 50 which is contoured to facilitate engagement by the user's finger. As can be seen in
Certain other aspects of nozzle 10 will now be explained with reference to
Flow valve 56 is urged against a stationary valve seat 60 by a coil spring 62.
As shown, coil spring 62 extends axially between flow valve 56 and a spring base member 64 that is fixed with respect to nozzle body 12. For example, base member 64 may be attached by one or more radial arms (not shown) to an inner surface of nozzle body 12. In a preferred embodiment, spring 62 may have a spring force falling in a range of 18 to 20 pounds, with a spring rate of 14.31 lbs/inch being used in one exemplary embodiment.
Flow valve 56 is pushed to the open position by a valve stem that is part of a dual shaft assembly 66 having a first outer shaft 68 and a second inner shaft 70. In particular, the valve stem is formed by an end of outer shaft 68. In this embodiment, flow valve 56 is actually a two-part valve having a primary poppet 72 and a secondary poppet 74. As shown, secondary poppet 74 is configured to form a valve seat for primary poppet 72. As illustrated in
Dual shaft assembly 66 is pushed toward the inlet 24 when the user grasps lever 36. In this embodiment, lever 36 is generally L-shaped, having a shorter portion 76 and a longer (grasping) portion 78. Pivot point 50 of trigger 38 is in this case located substantially at the intersection of shorter portion 76 and longer portion 78, as shown. Lever 36 is itself pivotally connected at the end of shorter portion 76 at a pivot point 80. As can be seen, pivot point 80 is in this case located near the top of nozzle body 12. A middle portion of shorter portion 76 engages the inner shaft 70 of dual shaft assembly 66 to move it toward the inlet 24. This causes outer shaft 68 to also move and open flow valve 56. When lever 36 is not being grasped (and when the hold open mechanism is not actuated), it is urged to the at rest potion shown in
As will now be described, dual shaft assembly 66 operates in conjunction with the nozzle's shut-off mechanism 84 to close flow valve 56 when the vehicle's tank is full. Mechanism 84 includes suitable locking elements, such as a plurality (e.g., two) rollers 86 carried by a roller holder 88. Holder 88 is attached to the underside of a diaphragm 90 and in this case includes a pair of lateral slots allowing the rollers 86 to move forward and aft with respect to the axial position of holder 88. Diaphragm 90 is itself connected on the other side to a piston 92 via a spring. Piston 92 can reciprocate in a sensing chamber in the nozzle body 12 defined by the diaphragm. Piston 92 is urged normally upward to the position shown in
As can be seen, one side of piston 92 is in fluid communication with an upstream side of the fuel flow path via a channel 94. The other side of piston 92 is in fluid communication with a sensing port at the tip of nozzle 26 via a channel 96. During a normal dispensing event, shaft 70 is locked with respect to shaft 68 (as shown in
As shown in
Referring now also to
It can thus be seen that the present invention provides a novel fuel dispensing nozzle. Although the invention has been described using preferred embodiments, configurations, and components, any combinations of these features are included within the scope of the invention. Moreover, variations and modifications as would be recognized by those skilled in the art are within the scope of the present invention. Explanation is by way of example only and the disclosure is not meant to be limiting.
This application is a continuation of application Ser. No. 16/879,394, filed May 20, 2020, which is based upon and claims the benefit of provisional application Ser. No. 62/850,541, filed May 20, 2019. The aforementioned applications are incorporated fully herein by reference for all purposes.
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Entry |
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International Search Report and Written Opinion dated Aug. 14, 2020 in corresponding PCT international application serial No. PCT/US2020/033813, all enclosed pages cited. |
Number | Date | Country | |
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20210362997 A1 | Nov 2021 | US |
Number | Date | Country | |
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62850541 | May 2019 | US |
Number | Date | Country | |
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Parent | 16879394 | May 2020 | US |
Child | 17391792 | US |