阅读说明：本技术 用于飞机飞行中加油的燃料软管组件 (Fuel hose assembly for aircraft in-flight refueling ) 是由 詹姆斯·皮特曼 于 2019-10-21 设计创作，主要内容包括：用于飞机飞行中加油的燃料软管组件包括：柔性内管,用于在压力下输送燃料；外罩,其包括多个刚性部分；和致动器,其配置成使刚性部分沿着柔性内管纵向移动。刚性部分可被致动器移动以在柔性内管上提供连续的纵向覆盖,从而当柔性内管被加压时能够抵抗柔性内管的径向扩张。刚性部分可被致动器进一步移动以在刚性部分之间露出柔性内管的纵向部分,从而当柔性内管未被加压时允许柔性内管弯曲。(A fuel hose assembly for use in aircraft in-flight refueling comprising: a flexible inner tube for conveying fuel under pressure; a housing comprising a plurality of rigid portions; and an actuator configured to move the rigid portion longitudinally along the flexible inner tube. The rigid portion is movable by the actuator to provide continuous longitudinal coverage on the flexible inner tube to resist radial expansion of the flexible inner tube when the flexible inner tube is pressurized. The rigid portions may be further moved by the actuator to expose longitudinal portions of the flexible inner tube between the rigid portions, thereby allowing the flexible inner tube to bend when the flexible inner tube is not pressurized.)

1. A fuel hose assembly for airborne fueling of an aircraft, comprising:

a flexible inner tube for conveying fuel under pressure;

a housing comprising a plurality of rigid portions; and

an actuator configured to move the rigid portion longitudinally along the flexible inner tube,

wherein:

said rigid portion being movable by said actuator to provide continuous longitudinal coverage over said flexible inner tube to resist radial expansion of said flexible inner tube when said flexible inner tube is pressurized; and is

The rigid portions may be further moved by the actuator to expose longitudinal portions of the flexible inner tube between the rigid portions, thereby allowing the flexible inner tube to bend when the flexible inner tube is not pressurized.

2. The fuel hose assembly of claim 1, wherein the rigid portion is coaxial and concentric with the flexible inner tube.

3. The fuel hose assembly according to claim 1 or 2, wherein:

each of said rigid portions being movable towards the other of said rigid portions so as to provide said continuous longitudinal coverage on said flexible inner tube; and is

Said each of said rigid portions being movable away from the other of said rigid portions to expose a longitudinal portion of said flexible inner tube between said rigid portions.

4. The fuel hose assembly of any preceding claim, wherein each of the rigid portions is configured to engage with another of the rigid portions so as to provide the continuous longitudinal coverage on the flexible inner tube.

5. The fuel hose assembly of any preceding claim, wherein each of the rigid portions is configured to releasably lock with another of the rigid portions so as to provide the continuous longitudinal coverage on the flexible inner tube.

6. A fuel hose assembly according to any preceding claim, wherein each of the rigid portions is movable to overlap another part of the rigid portion so as to provide the continuous longitudinal coverage on the flexible inner tube.

7. The fuel hose assembly of any preceding claim, wherein each of the plurality of rigid portions is a discrete element distinct from the other rigid portions.

8. The fuel hose assembly of claim 7, wherein the rigid portion comprises a similarly shaped segment of the outer cover.

9. The fuel hose assembly according to any one of claims 1 to 6, wherein each of the plurality of rigid portions is integral with another of the rigid portions.

10. The fuel hose assembly of claim 9, wherein the plurality of rigid portions collectively define the outer cover in the form of a helix.

11. The fuel hose of any preceding claim, wherein the actuator comprises:

a first control cord configured to move the rigid portion to overlie the flexible inner tube; and

a second control cord and a plurality of auxiliary cords configured to move the rigid portion to expose a longitudinal portion of the flexible inner tube.

12. The fuel hose assembly of claim 11, wherein a first end of each of the auxiliary cords is connected to a respective one of the rigid portions and a second end of each of the auxiliary cords is connected to an end region of a second control cord.

13. The fuel hose assembly of any preceding claim, wherein each of the rigid portions comprises a profile configured for aerodynamically stabilising the fuel hose in flight.

14. The fuel hose assembly of any preceding claim, wherein each of the rigid portions comprises a drag surface for providing aerodynamic assistance to the actuator to move the rigid portion longitudinally along the flexible inner tube.

15. The fuel hose assembly of any preceding claim, further comprising a further flexible inner tube for conveying fuel under pressure, wherein the rigid portion is movable by the actuator to cover both of the flexible inner tubes and to expose longitudinal portions of both of the flexible inner tubes.

Background

The present invention relates to a fuel hose assembly for in-flight (re) refuelling of aircraft.

In-flight refuelling (IFR) involves transferring fuel from one aircraft ("tanker") to another ("tanker") during flight. IFR (also known as air refuel or air-to-air refuel) has become a well established method for extending the range or cruise time (or increasing the takeoff payload) of military aircraft. Typically, fuel dispensers are based on passenger aircraft that are redesigned or retrofitted specifically for fueling operations, while fuel receiving machines are typically fighter aircraft, or possibly bombers or scouts.

Today, there are two different IFR methods in widespread use: flight telescope (flying boom) and probe-and-drogue (probe-and-drogue).

An aerial telescoping tube is attached to the rear of the fuel dispenser and comprises a rigid, telescoping and articulated tube with a nozzle at one end. The telescoping tubes include flight control surfaces that are movable to generate aerodynamic forces for controlling the telescoping tubes in flight. To refuel, the fuel receiver is first placed behind the fuel dispenser in a fleet that flies straight and horizontally. The telescoping tubes are then extended and adjusted by the telescoping tube operator at the fuel dispenser to direct the nozzle into a receiver on a subsequent fuel receiver. Once the nozzle is securely inserted and locked into the receiver, fuel is pumped from the fuel dispenser to the fuel receiver. When the required amount of fuel has been transferred, the telescope operator disconnects the nozzle from the receiver and the two aircraft are then free to break the formation.

In the probe and taper sleeve system, the fuel dispenser is equipped with a hose. A drogue (or basket) similar to a badminton shuttlecock is attached to one end of the hose. The other end is connected to a Hose Drum Unit (HDU) and the hose is wound around the HDU when not in use. The probe is a rigid tubular arm that extends from the head or body of the fuel receiver. The probe is typically retractable so that it can be stored when not in use.

For refueling, the hose and the drogue are pulled out of the back and below of the fuel dispenser while the fuel dispenser is in straight and horizontal flight. The hose stably flies through the taper sleeve in the form of a badminton. The pilot of the fuel receiver places the fuel receiver behind and below the fuel dispenser. The pilot then flies the fuel receiver toward the fuel dispenser to insert the extended probe into the funnel-shaped cone. When the probe is correctly engaged with the taper sleeve, the fuel is pumped from the fuel dispenser to the fuel receiver. As the oil subject moves back and forth, the motor in the HDU controls the hose to retract and extend, thereby maintaining the correct amount of tension to prevent undesired flexing of the hose. When the required fuel quantity is transferred, the probe pipe is disconnected with the taper sleeve, and the formation of the two airplanes is interrupted.

Unlike flight telescope systems, the probe and taper sleeve system does not require a dedicated telescope operator on the tanker. The design of the fuel dispenser is also simpler. In addition, the oiling machine can be provided with a plurality of hoses and taper sleeves so that two or more oil receiving machines can be oiled at the same time, and the flying telescopic sleeve system can only be used for oiling one oil receiving machine at a time. On the other hand, the probe-and-cone system has a lower fuel flow rate than the flight telescope system, which means a longer refueling time. In addition, the probe and cone systems are more susceptible to adverse weather conditions and turbulence, and require a high level of training and retraining of the flight crew to connect the fuel receiver to the cone. In addition, the probe and taper sleeve system requires that all oil receiving machines are provided with an oil filling probe. Although IFR has become a routine undertaking for military aircraft, it has not found any significant degree of application in commercial aircraft operations, despite its enormous potential advantage in cost savings due to reduced fuel consumption. One reason for this is that the components of the IFR system themselves appear to be unsuitable for use with passenger aircraft. For example, the amount of fuel that needs to be transferred to a passenger aircraft is much larger than, for example, that required by a fighter aircraft, and if the refueling is to be completed in a reasonable amount of time, the fuel hose needs to be made larger and more robust to enable it to operate at higher pressures. However, this may be impractical because the hose becomes cumbersome. Also, for safety reasons, the separation distance between commercial aircraft will need to be greater than the separation distance between military aircraft. This indicates that a longer hose is required, but this can be problematic because the "whip" effect of the length results in greater lateral movement of the hose in the air.

For these reasons, at least the type of IFR system used by military operators does not appear to be suitable for large civilian aircraft and is unlikely to gain security certification for commercial airline operations.

The present invention therefore seeks to provide a fuel hose suitable for in-flight (re) refuelling of civil and military aircraft.

Disclosure of Invention

According to one aspect of the present invention there is provided a fuel hose assembly for in-flight refueling of an aircraft, comprising: a flexible inner tube for conveying fuel under pressure; a housing comprising a plurality of rigid portions; and an actuator configured to move the rigid portion longitudinally along the flexible inner tube, wherein: said rigid portion being movable by said actuator to provide continuous longitudinal coverage over said flexible inner tube to resist radial expansion of said flexible inner tube when said flexible inner tube is compressed; and the rigid portions may be further moved by the actuator to expose longitudinal portions of the flexible inner tube between the rigid portions to allow the flexible inner tube to bend when the flexible inner tube is uncompressed.

As used herein with respect to the rigid portion of the fuel hose assembly, "rigid" refers to sufficiently rigid or stiff to be able to resist the radial pressure of the fuel in the flexible inner tube so as to prevent (or at least limit) undesired radial expansion of the flexible inner tube.

In the first (compressed) state, the rigid sections are brought together to form a continuous line axially along the flexible inner tube, thereby providing continuous coverage along the outer cylindrical surface of the flexible inner tube. When fuel passes through the flexible inner tube, for example during an in-flight (re) refuelling operation, radial pressure is exerted by the fuel on the wall of the flexible inner tube. The radial pressure is inhibited by the rigid portion, thereby preventing (or at least limiting) radial expansion (bulging) of the flexible inner tube. Significant radial expansion of the flexible inner tube is undesirable because it can lead to rupture of the inner tube (catastrophic structural failure).

Since the fuel pressure is suppressed by the outer rigid portion rather than by the wall of the flexible inner tube itself, the wall can be made relatively thin. Thus, the fuel hose assembly is able to handle high pressure levels without becoming bulky.

In addition to providing a pressure dampening function, the outer rigid portion imparts a longitudinal stiffness (i.e., a stiffness along the length of the fuel hose assembly) to the fuel hose assembly in the first (compressed) state, which enhances the stability of the fuel hose assembly in air and prevents (or at least reduces) an undesirable "whiplash" effect. Thus the fuel hose assembly is less susceptible to adverse weather conditions and turbulence than conventional fuel hoses, and the improved stability of the fuel hose assembly in the air means that the level of pilot skill and training required to connect the hoses can be reduced.

In the second (relaxed) state, the rigid portions are separated from each other by a gap. In this case, the fuel hose assembly is easily bent, and thus can be conveniently wound around the hose drum unit mounted on the aircraft.

The rigid portions are thus selectively movable by the actuator to provide continuous outer longitudinal coverage along the flexible inner tube to resist outward expansion of the flexible inner tube under fuel pressure and to expose longitudinal portions of the flexible inner tube between the rigid portions to allow the flexible inner tube to flex when fuel pressure is removed.

The present invention thus provides a fuel hose assembly which is capable of handling high fuel pressures and flow rates, yet is not overly bulky, has a high degree of longitudinal stiffness and stability when extended in air, and can be conveniently stored in a space-saving manner when not in use. Thus, the fuel hose assembly is well suited for use in commercial (and military) in-flight refueling operations associated with manned and unmanned aircraft.

The rigid portion may be coaxial and concentric with the flexible inner tube.

Each of the rigid portions may be moved towards the other of the rigid portions to provide a continuous longitudinal coverage over the flexible inner tube; and each of the rigid portions is movable away from the other of the rigid portions to expose a longitudinal portion of the flexible inner tube between the rigid portions.

Each of the rigid portions may be configured to engage another of the rigid portions to provide a continuous longitudinal coverage over the flexible inner tube.

Each of the rigid portions may be configured to releasably lock with another of the rigid portions to provide a continuous longitudinal coverage over the flexible inner tube.

Each of the rigid sections may be moved to overlap another portion of the rigid section to provide continuous longitudinal coverage on the flexible inner tube. The overlap may be provided by using both convex and concave forms of the rigid portion. For example, one end of each rigid portion may provide a male connection while the other end provides a female connection. Alternatively, some rigid sections may have male connections at both ends thereof, while other rigid sections have female connections at both ends thereof, the male and female rigid sections being alternately positioned along the flexible inner tube. Various such arrangements are contemplated and all such arrangements are within the scope of the claimed invention, as long as the rigid portions partially overlap each other.

Each of the plurality of rigid portions may be a discrete element distinct from the other rigid portions.

The rigid portion may comprise a similarly shaped segment of the outer cover.

Each of the plurality of rigid portions may be integral with another of the rigid portions.

The plurality of rigid portions may collectively define a helical form of the housing.

The actuator may include: a first control cord configured to move the rigid portion to cover the flexible inner tube; and a second control cord and a plurality of auxiliary cords configured to move the rigid portion to expose a longitudinal portion of the flexible inner tube.

The first end of each auxiliary cord may be connected to a respective one of the rigid portions, and the second end of each auxiliary cord may be connected to an end region of the second control cord.

Each of the rigid portions may include a profile configured for aerodynamically stabilizing the fuel hose in flight.

Each of the rigid portions may include a drag surface for providing aerodynamic assistance to the actuator to move the rigid portion longitudinally along the flexible inner tube.

The fuel hose assembly may comprise a further flexible inner tube for conveying fuel under pressure, the rigid portion being movable by the actuator to cover the two flexible inner tubes and expose longitudinal portions of the two flexible inner tubes.

Drawings

Examples will now be described with reference to the accompanying drawings, in which:

figure 1 shows a fuel dispenser comprising a fuel hose assembly according to a first example of the invention;

FIGS. 2a and 2b show the fuel hose assembly in a flexible state;

FIG. 2c shows a cross-section of a rigid segment of the fuel hose assembly;

FIGS. 3a and 3b show the fuel hose assembly in a rigid state;

FIGS. 4a and 4b illustrate an apparatus for providing additional rigid segments to a fuel hose assembly;

FIG. 5 shows a second example of a fuel hose assembly; and

fig. 6a-c show an arrangement for providing a rigid collar for a fuel hose assembly.

Detailed Description

Figure 1 shows a fuel dispenser comprising a fuel hose assembly 100 coiled on a motorized hose drum unit 50 and provided with a fuel supply carried by the fuel dispenser.

FIG. 2a shows an exemplary portion of the fuel hose assembly 100 having a length L and a longitudinal axis X-X'. The fuel hose assembly 100 comprises an elongate tubular core 200, a plurality of rigid segments 301 and 311, and first and second control cords 401, 402 and auxiliary cords (only one auxiliary cord 402c is shown in fig. 2 a). Rigid segments 301 and 311 are separated (spaced apart) by gap G. It should be understood that only some of the rigid segments 303 and 308 of the fuel hose assembly 100 are visible in FIG. 2a, as this figure only shows a portion of the fuel hose assembly 100. For ease of understanding the following description, FIG. 2b shows an enlarged detail of a portion of the fuel hose assembly 100 of FIG. 2 a.

The tubular core 200 includes an inner cylindrical surface 200a and an outer cylindrical surface 200 b. In this example, the tubular core 200 has a length of about 15m, an outer diameter of about 66mm and an inner diameter (or bore diameter) of about 60 mm. Thus, the tubular core 200 has a wall thickness (i.e., the distance between the inner and outer cylindrical surfaces 200a, 200 b) of about 6 mm. In this example, the tubular core 200 is constructed of a rubber material (e.g., nitrile rubber) such that the tubular core 200 is flexible (i.e., can be bent and/or twisted) and resilient. The tubular core 200 is suitable for fueling an aircraft, for example, a liquid fuel such as kerosene, or a gaseous fuel.

The rigid segments 301 and 308 are similar to each other in structure and function. One of the rigid segments 306 will now be described separately by way of example. It will be appreciated that the exemplary rigid segment 306 represents other similar rigid segments 301, 305, 307, 308, and thus these are also described. It will also be appreciated that this and other examples of the invention may include almost any number of rigid segments, e.g., tens or hundreds. In the following description, the terms "front" and "rear", "left" and "right", and "upper" and "lower" are used merely for convenience of explanation and do not limit the claimed invention.

The exemplary rigid section 306 includes a tubular body having a cylindrical central portion and a rear portion and a front portion (to the right in fig. 2a and 2 b) forming a truncated cone. In this example, rigid section 306 is constructed of a carbon composite material. Alternatively, rigid section 306 may be constructed of some other high strength, rigid, and lightweight material, such as a metal alloy, e.g., a titanium alloy, or a polymer.

Referring also to fig. 2c, the right part of which shows a front view of the tubular body and the left part of which shows a rear view, a through hole 306a (not visible in fig. 2a and 2 b) with a circular cross-section extends between the front and rear openings of the body. At the front and central portions of the body, the through-hole 306a has a constant diameter, while at the rear of the body, the hole 306a widens (diverges) and reaches a maximum diameter at the rear opening of the body. The widened (divergent) portion of the bore 306a is sized and shaped to snugly receive the (frusto-conical) forward portion of the other rigid section.

The exemplary rigid segment 306 surrounds (encircles) a particular portion of the tubular core 200 of the fuel hose assembly 100. Thus, the example rigid segment 306 is coaxial and concentric with the tubular core 200. The diameter of that portion of the through hole 306a that extends through the front and central portions of the main body (i.e., the portion of the hole 306a having a constant diameter) is sized to be substantially the same as the outer diameter of the tubular core 200. Thus, the inner surface 306b of the body (i.e., the wall defining the through-hole 306a of the body) is in contact with the outer cylindrical surface 200b of the tubular core 200 relative to the front and central portions of the body of the rigid section 306. Thus, the inner surface 306b of the body is located radially and immediately adjacent the outer cylindrical surface 200b and extends lengthwise along the outer cylindrical surface 200 b. The contact is light enough to overcome the friction between the surfaces 306b, 200b to allow the body of the rigid section 306 to slide (axially) along (upon) the outer cylindrical surface 200b of the tubular core 200, as will be described later herein. The endmost rigid section 311 (to the right in the sense of fig. 2a, but not shown therein) is fixedly secured to the tubular core 200. Unlike the other rigid segments 301 and 310, the fixed rigid segment 311 cannot move axially relative to the tubular core 200.

The exemplary rigid section 306 also includes a pair of narrow apertures or channels 306c (see FIG. 2c) for receiving the control cords 401, 402. The two channels 306c are positioned 180 degrees from each other around the circumference of the body, i.e., such that the channels 306c are opposite each other. The control cords 401, 402 will now be described.

Referring again to fig. 2a, the first control cord 401 extends from its first end 401a (to the left in the sense of fig. 2a) through the upper channel 306c of the rigid segments 301 and 311 (from left to right) and around a pulley (not shown) so as to extend rearwardly in the opposite direction (from right to left) to its second end 401 b. The first control cord 401 is free to slide axially in the upper channel 306 c. First end 401a is slightly enlarged so that it cannot enter upper channel 306c of the nearest rigid section 301.

The second control cord 402 extends from its first end 402a (to the left in the sense of fig. 2a) through the lower channel 306c (from left to right) of the rigid segments 301 and 311 to its second end 402 b. The second control cord 402 is free to slide axially in the lower channel 306 c. Second end 402b is slightly enlarged so that it cannot enter lower channel 306c of the nearest rigid section 311. Each of the rigid segments 301-311 is connected to a first end 402a of a second control tether 402 by an auxiliary tether (only one auxiliary tether 402c is shown in fig. 2a for clarity of the drawing). The auxiliary ropes have different lengths, the shortest one connecting the first end 402a of the second control rope 402 to the nearest rigid segment 301, and the longest one connecting the first end 402a of the second control rope 402 to the farthest rigid segment 311, the length of the intermediate auxiliary ropes becoming progressively longer. When the rigid segments 301-308 are separated by the gap G (as shown in FIG. 2a), each auxiliary cord 402c is in a tensioned (extended) state.

In this example, the first control cord 401 and the second control cord 402 and the auxiliary cords comprise steel cords. Alternatively, the cords 401, 402 may be constructed of some other material having high tensile strength and flexibility, such as a carbon fiber composite material.

In fig. 2a, the tubular core 200 is devoid of fuel. In addition, the rear portion of each rigid segment 304-308 is separated from the front portion of the adjacent rigid segment 303-307 by a gap G. Due to the gap G between the rigid segments 303 and 308, and due to the flexibility of the tubular core 200, the fuel hose assembly 100 can be bent by applying a bending force. The bending force will cause the longitudinal axis X-X' of the fuel hose assembly 100 to change from a straight line to a curved line. Therefore, it will be appreciated that the fuel hose assembly 100 is in a relaxed state, as shown in fig. 2a, in which the fuel hose assembly is easily bent. In short, the fuel hose assembly 100 is in a bendable state. Thus, the fuel hose assembly 100 can be conveniently rolled (coiled) onto a motorized hose drum unit 50 (see FIG. 1) mounted on the fuel dispenser. The use of the fuel hose assembly 100 in an aircraft in-flight (re) refuelling operation will now also be described with reference to figures 3a and 3 b. For ease of understanding the following description, FIG. 3b shows an enlarged detail of a portion of the fuel hose assembly 100 as shown in FIG. 3 a.

First, the fuel dispensers and fuel receivers are set up in a flight formation, wherein the two aircraft are controlled to maintain a fixed position relative to each other. The fuel hose assembly 100 is then extended (loosened or untwisted) from the motorized hose drum unit 50 of the fuel dispenser toward the fuel receiver.

Once the fuel hose assembly 100 is stretched in air, a pulling force is applied to the second end 401b of the first control cord 401 (to the left in the sense of fig. 2a and 3 a). Due to the pulley arrangement, the upper part of the first control cord 401 is displaced in the pulling direction (to the left), while the lower part of the first control cord 401 is displaced in the opposite direction (to the right) by the upper channel 306c of the rigid segments 301 and 311. Therefore, the upper portion of the first control rope 401 is lengthened and the lower portion is shortened.

When the enlarged portion of the first end 401a of the first control cord 401 reaches and contacts the first rigid segment 301, the continued pulling force overcomes the frictional forces that exist between the inner surface 306b of the body of the first rigid segment 301 and the outer cylindrical surface 200b of the tubular core 200. Thus, the first rigid segment 301 moves towards the second (adjacent) rigid segment 302 (to the right). The frusto-conical shape of the front portion of the first rigid section 301 helps to guide the front portion into the rear portion of the second rigid section 302. Thus, the front portion of the first rigid section 301 is closely received in the rear portion of the second rigid section 302, which abuts the wall of the rear aperture 306 a. I.e. the two segments 301, 302 are in contact with each other. Thus, the gap G previously existing between the first rigid segment 301 and the second rigid segment 302 is closed (eliminated).

As the pulling force on the first control cord 401 continues, the first and second rigid segments 301, 302 slide axially (to the right) on the tubular core 200. In a similar manner to the previous, the front portion of the second rigid section 302 is closely received in the rear portion of the third rigid section 303, which abuts the wall of the rear aperture 306 a. Thus, the gap G previously existing between the second rigid segment 302 and the third rigid segment 303 is closed (eliminated).

The pulling force on the first control cord 401 continues until all but the endmost rigid segment 311 (which is to be secured back around the tubular core 200) is axially (to the right) displaced relative to the tubular core 200 and brought together to close the gap G. Thus, the rigid segments 301-311 (which in this example are integral elements) are placed along a continuous line along the tubular core 200. In this position (see FIG. 3a), the constant diameter bore segments of rigid segments 301 and 311 are connected together to provide a constant diameter bore that extends continuously between the two endmost rigid segments 301, 311 of the fuel hose assembly 100. Furthermore, the inner surface 306b (bore wall) of the body of the continuous rigid section 301-311 is in contact with the outer cylindrical surface 200b of the tubular core 200 and together they provide a continuous coverage axially along the outer cylindrical surface 200 b.

Once the rigid segments 301 and 311 have been closed (compressed) together as described above, the portion of the tubular core 200 (the left side in the sense of fig. 3a) that was initially covered by the first rigid segment 301 will be exposed. As will be explained later herein, during a refueling operation, the length of the barrel core 200 will be covered in order to inhibit pressure exerted on the barrel core 200 by fuel flowing therein. In this example, additional rigid segments are provided for this purpose, as described below.

FIG. 4a shows the fuel hose assembly 100 being unfastened from the motorized hose drum unit 50 prior to the closing (compression) of the rigid segments 301 and 311 as described above. One end (the left end in the sense of fig. 2a and 3a) of the tubular core 200 is joined by a joining means 200c to the distal end of a rigid tube 500 having substantially the same outer diameter and inner bore as the tubular core 200. The engaging means 200c may be a threaded connector or an adhesive or the like. The proximal end of the rigid tube 500 includes an inlet 500a for receiving fuel from a reservoir on the fuel dispenser. The rigid tube 500 is provided at the outer edge of the motorized hose drum unit 50. Furthermore, the rigid tube 500 forms part of the motorised hose drum unit 50 and is rotatable therewith. In this example, the rigid tube 500 is made of steel. Alternatively, the rigid tube 500 may be constructed of some other strong (pressure resistant) material, such as a carbon fiber composite.

An additional rigid section 501 and 503 is provided on the distal portion of the rigid tube 500, having a small radius of curvature (exaggerated in fig. 4 a). The additional rigid segments 501 and 503 are generally similar in structure to the rigid segments 301 and 311 described above, except that the through-hole is slightly enlarged to allow the additional rigid segments 501 and 503 to slide over the slightly curved distal portion of the rigid tube 500. Alternatively, the ends of the rigid tube 500 may be made straight, in which case no enlarged through-hole is required.

When the rigid segments 301 and 311 have been closed (compressed) on the tubular core 200 as described above, the additional rigid segments 501 and 503 slide axially (to the right in the sense of fig. 4 a) on the rigid tube 500 and on the exposed end of the tubular core 200. In this example, when the rigid tube 500 rotates with the motorized hose drum unit 50 and stops once the fuel hose assembly 100 is fully opened, the additional rigid segments 501 and 503 slide under gravity and/or their own forward momentum onto the tubular core 200. Alternatively, the additional rigid segments 501-503 may be configured to be moved onto the tubular core 200 using the control cords 401, 402. Thus, as shown in fig. 4b, the outer cylindrical surface 200b of the end of the tubular core 200 is covered by a continuous additional section 501-503. Thus, the entire axial length of the tubular core 200 is continuously covered by the combination of the continuous rigid sections 301-311 and the additional sections 501-503.

Thus, the fuel hose assembly 100 is in a rigid (hardened) state that resists bending. That is, the fuel hose assembly 100 is in an inflexible state. In this state, the fuel hose assembly 100 has a structural load-bearing resistance similar to a rigid sleeve. Thus, the stability of the fuel hose assembly 100 in air is enhanced.

The distal end of the fuel hose assembly 100 (to the right in the sense of fig. 3a) is directed towards the rigid fuel nozzle of the oil receiver. To this end, a drogue (not shown) may be provided on the fuel hose assembly 100. The distal end of the tubular core 200 is received in a rigid fuel nozzle, the end of which is shaped to abut the front of the endmost rigid segment 311. Thus, the two aircraft are tethered together by the fuel hose assembly 100. Fuel, for example liquid kerosene, is pumped under pressure through the tubular core 200 (from left to right in the sense of fig. 3 a). The level of gauge pressure of the fuel in the tubular core 200 may be in the range of about 690 to 1380kPa (about 6.9 to 13.8 bar or 100 to 200 psi).

The fuel exerts a pressure P on the inner cylindrical surface 200a of the tubular core 200 in a radial direction (i.e., a direction perpendicular to the longitudinal axis X-X'). The radial pressure P is transmitted through the wall of the tubular core 200 and tends to push the cylindrical outer surface 200b outwards. Since the outer cylindrical surface 200b is in contact with the inner surface 306b (bore wall) of the body of the continuous rigid section 301 + 311, the rigid section 301 + 311 resists radial pressure, thereby preventing undesired outward displacement (bulging or expansion) of the outer cylindrical surface 200 b. In other words, the rigid section 301 and 311 limit the fuel pressure P in the tubular core 200.

Since in this example the additional rigid segments 501-503 have slightly enlarged through holes, the end of the tubular core 200 covered by the additional rigid segments 501-503 will expand slightly in the radial direction, but the expansion will be minimal and within tolerable limits. Indeed, it will be appreciated that there may be a small (partial) circumferential gap between the outer cylindrical surface 200b of the tubular core 200 and the inner surface 306b (bore wall) of the one or more rigid sections 301 and 311 prior to fuel pressurization. Any such small gap will be filled by the radial expansion of the tubular core 200 when pressurized with fuel, the amount of expansion being minimal and within tolerable limits. The selection of the building materials for the tubular core and rigid portions will preferably take into account the coefficient of expansion of the materials, including the temperatures experienced at the level at which airborne fueling operations are carried out, to ensure that any gaps are within design tolerances.

When the required amount of fuel has been transferred from the fuel dispenser to the fuel receiver, the distal end of the tubular core 200 (on the right in figure 3a) is disconnected from the fuel nozzle of the fuel receiver. Thus, the two planes are not tied together and can freely break the formation. The tubular core 200 is evacuated to remove residual fuel. Thus, the radial pressure exerted by the fuel is eliminated and the elastic tubular core 200 is relaxed. As described above, there may then be a small gap between the outer cylindrical surface 200b of the tubular core 200 and the inner surface 306b (bore wall) of any rigid segments 301 and 311.

A pulling force is applied to the first end 402a of the second control cord 402 (to the left in the sense of fig. 2a and 3 a). Thus, the second control cord 402 is axially displaced in the pulling direction (to the left) through the lower channel 306c of the rigid segment 301-308. When the second control tether 402 is displaced, the slack in the auxiliary tether connecting the second control tether 402 to the rigid segment 301-311 is taken up. Thus, the auxiliary cord is tensioned and continued pulling of the second control cord 402 causes the rigid segments 301 and 311 to disengage from each other and slide axially (to the left) along the tubular core 200. The pulling force on the second control string 402 continues until all the auxiliary strings are extended, so that the gap G is re-established between the rigid segments 301 and 311. That is, the longitudinal portion of the tubular core 200 is not covered (exposed). The movement of the first rigid segment 301 (to the left) also causes the first control cord 401 to be pulled back to its original position (see fig. 2 a). (alternatively, the first control cord 401 may be pulled back to its original position before a pulling force is applied to the second control cord 402). In addition, other rigid elements 501-503 are slid back over the rigid tube 500 from the tubular core 200. Accordingly, the fuel hose assembly 100 returns to the state shown in fig. 2 a. That is, the fuel hose assembly 100 returns to the bendable state. Thus, the deformable fuel hose assembly 100 is rolled back onto the fuel dispenser's motorized hose drum unit 50.

It will be appreciated that the particular spacing of the rigid segments 303 and 308 shown in FIG. 2a is merely exemplary and not necessarily optimal for bending deformation of the fuel hose assembly 100.

Referring now to fig. 5, in another example, a fuel hose assembly 600 includes two tubular cores 700, similar to that described above. In this dual hose configuration, the control cord passes through rigid segment 800 and is operable to move the rigid segment along tubular core 700 in the manner described herein above. Each of the rigid segments 800 comprises two part-cylindrical portions surrounding a respective tubular core 700. The partially cylindrical portions are connected by a bridge portion 801 comprising a rigid lattice structure 701. Each part-cylindrical portion includes a tapered profile to provide fuel hose assembly 600 with enhanced stability in air.

It will be understood that the invention has been described with respect to preferred examples thereof, and that it can be modified in many different ways without departing from the scope of the invention as defined by the appended claims.

Although in the first example described above the exposed end of the tubular core is provided with an additional rigid section from a rigid tube forming part of the motorised hose drum unit, in other examples the exposed end of the tubular core is protected from fuel pressurisation by other means, for example as follows.

Referring to FIG. 6a, as described above, the rigid segments 301 and 311 have been closed (compressed) together using the first control string 401. One end (on the left side of fig. 6 a) of the tubular core 200 is connected to the fuel inlet 500a of the motorized hose drum unit 50. Thus, the exposed (uncovered) portion of the tubular core 200 extends between the endmost rigid section 301 and the end of the tubular core 200.

Turning to fig. 6a and 6b, a pair of elongated cylindrical half shells 900a, 900b are each located at the side of the tubular core 200. In this example, the half shells 900a, 900b are made of steel. Alternatively, the half shells 900a, 900b may be constructed of some other strong (pressure resistant) material, such as a carbon fiber composite. The half shells 900a, 900b are directed laterally (inwardly) towards the tubular core 200 (as indicated by the arrows in fig. 6 b) and contact each other (as shown in fig. 6 c) to surround (encircle) the tubular core 200. In this example, the half-shells 900a, 900b are supported and moved by actuators (not shown in the figures) controlled by the fuel dispenser crew, or can be operated automatically when the closing (compression) of the rigid segments 301 and 311 is completed.

The inner curved surfaces of the half-shells 900a, 900b thus form an axial through hole having a constant diameter, which is substantially the same as the outer diameter of the tubular core 200. Thus, in this closed position, the inner curved surfaces of the half shells 900a, 900b are in contact with the outer cylindrical surface 200b of the tubular core 200 such that the half shells 900a, 900b provide a close-fitting collar on the tubular core 200. Furthermore, the entire axial length of the tubular core 200 is continuously covered by the combination of the continuous rigid section 301 and 311 and the pair of half-shells 900a, 900 b. Thus, as described above, the fuel hose assembly 100 is in a rigid (hardened) state in which it resists bending.

During the refuelling operation, the radial pressure exerted by the fuel on (a portion of) the inner cylindrical surface 200a of the tubular core 200 (covered by the half-shells 900a, 900 b) is suppressed by the rigid inner curved surfaces of the half-shells 900a, 900b, in the same way as the inner surface 306b (the hole wall) of the body of the continuous rigid section 301 and 311 suppresses the pressure. In this regard, the half shells 900a, 900b are functionally identical to the rigid segments 301-311.

In this example, the actuator can apply an inward force to resist the radial fuel pressure, thereby preventing the half shells 900a, 900b from moving outward away from the tubular core 200. Alternatively, the half shells 900a, 900b may be configured to releasably lock together, thereby eliminating the need for an inward force of an actuator to secure the half shells 900a, 900b in place relative to the tubular core 200. In such an example, the actuator may be laterally separated from the half shells 900a, 900b after the half shells 900a, 900b have been releasably locked together and prior to pressurizing the tubular core 200.

Once the refuelling operation has been completed and the tubular core 200 has released the fuel pressure, the half-shells 900a, 900b are laterally moved away from the tubular core 200 by the actuators and returned to their original position. The rigid segments may then be relaxed (separated from each other) using the control cords 401, 402 in the manner described herein above. In one example, the control cords 401, 402 extend through axial passages provided in the half shells 900a, 900 b.

In addition to the additional rigid segments 501-503 and half-shells 900a, 900b described herein above, other ways of covering the exposed end of the tubular core 200 prior to pressurization are contemplated. All of which are within the scope of the claimed invention as long as they function to suppress fuel pressure and enhance the rigidity of the fuel hose assembly 100.

In the first example described above, the second control cord extends through the lower channel of the rigid section. Although this may help guide the path of the rigid segments, it will be appreciated that the cord need not extend through the channel in this manner to perform its function of separating the rigid segments. Thus, in one example, the lower channel of the rigid segment is omitted and the second control cord extends along the hose assembly 100 outside of the rigid segment.

In one example, the second control cord is attached to only one auxiliary cord, which is in turn attached to the first rigid section. The first rigid section is attached to the second rigid section by another auxiliary rope, the second rigid section is attached to the third rigid section by another auxiliary rope, and so on, so that all rigid sections are attached one after the other. As each rigid section moves axially along the tubular core, as the auxiliary cord connecting the rigid sections becomes taut, it will tend to tighten the next rigid section. In this way, a gap is provided between the rigid segments. Although in the first example described above the rigid segments are actuated by two control cords (and auxiliary cords), it will be appreciated that the actuator may comprise a different number of cords, including a single cord, for moving the rigid segments. Further, some rigid segments may be actuated by one or more cords, while other rigid segments may be actuated by one or more different cords. Examples are envisaged in which each of a plurality of cords is connected to a particular set of rigid segments by an auxiliary cord so that each set of rigid segments can be controlled independently of the other sets of rigid segments. All of these cord arrangements are within the scope of the claimed invention in terms of single and multi-hose assemblies, as long as they are capable of selectively moving the rigid segments together to provide continuous longitudinal coverage over the tubular core, and moving the rigid segments apart to expose portions of the tubular core between the rigid portions, thereby allowing the tubular core to bend.

Although in the first example described above each rigid segment has a unitary construction, in another example each rigid segment comprises two or more discrete portions which are joined together to form the rigid segment. For example, the forward portion of the truncated cone shape may be manufactured separately from the remainder of the body of the rigid section and then attached thereto.

The wall of the bore forming the body of the rigid section that is in contact with the outer cylindrical surface of the tubular core may comprise a different material than the remainder of the rigid section. For example, the walls of the bore may comprise a relatively more rigid material, such as a metal alloy, while another portion of the rigid section may comprise a relatively less rigid material, such as a polymer. In this way, the walls of the bore will be sufficiently rigid to contain the pressure exerted by the fuel in the tubular core, while the exterior of the rigid section may be relatively resilient and therefore able to absorb impacts or shocks from other objects in use.

In the first example described above, the front portions of rigid segments are received in the rear portions of adjacent rigid segments such that the rigid segments partially overlap each other when compressed together. In another example, when the gap between rigid segments is closed, there is no overlap between adjacent rigid segments. In one such example, the rigid segments are simple cylinders, the ends of which abut each other so as to close the gap without overlapping.

In one example, the rigid segments are configured to releasably lock together when they are compressed to close the gap. For example, a circumferential lip may be provided on the frusto-conical front end of each rigid section and a complementary circumferential groove in the wall of the bore at the widened rear portion of the rigid section, such that the lip will engage with the groove when the front portion is inserted into the rear portion to lock the rigid sections together. The lip can then be released from the groove by applying sufficient tension to the second control cord. Alternatively, the rigid segments may lock together with radial fuel pressure exerted on the tubular core and release from each other with the pressure removed.

In one example, a lubricant is provided between the rigid segments and the tubular core to facilitate passage of the rigid segments over the tubular core to open and close the gaps between the rigid segments. The lubricant may comprise an oil or a gel. The lubricant may include a surface coating, such as a PTFE layer, on one or both of the rigid section and the tubular core. In a similar manner, a lubricant may be provided to assist in the axial passage of the control cord through the rigid section.

Although in the first example described above the fuel hose assembly comprises a plurality of rigid segments of similar shape and size, it will be appreciated that the assembly may alternatively comprise rigid portions of different shapes and/or sizes (including different axial lengths). Various forms of rigid portion are contemplated, including forms that may improve aerodynamic stability or provide lift to the fuel hose assembly in the air. The rigid portion may be shaped to cause air resistance to assist the rigid portion in moving along the tubular core under the pulling force of the control cord. The differently shaped rigid portions may be selected such that when they are compressed together they form the fuel hose assembly into a predetermined shape, for example with a bend in one or more planes, which may contribute to the aerodynamic stability or stiffness of the fuel hose assembly. Or a different shape of the rigid portion may be selected to account for the longitudinal profile of the compressed fuel hose assembly that is suitable for use under certain conditions, such as air velocity. For both single and multi-hose assemblies, all of these different shapes and sizes of rigid sections are within the scope of the claimed invention, as long as they can be selectively moved together to provide continuous longitudinal coverage over the tubular core, and moved apart to expose portions of the tubular core between the rigid sections, thereby allowing the tubular core to bend.

Although in the first example described above the axial length of the gaps is uniform such that the rigid segments are regularly spaced, in another example at least one gap has a different axial length than the other gaps such that the rigid segments are irregularly spaced. In the first example described above, the fuel hose assembly includes a plurality of discrete (distinct) rigid segments that come together to form a continuous outer covering over the tubular core. In another example, a plurality of rigid sections are connected to collectively define a continuous spiral (spiral) around the tubular core that is extendable and compressible (via a control cord as described above) to open and close the gap between the sections of the spiral.

In the second example described above, the fuel hose assembly comprises two tubular cores, while in other examples the multi-fuel hose assembly comprises a greater number of tubular cores, for example three, four, five, six, seven, eight, nine, ten or more tubular cores. Such a multi-fuel hose arrangement may provide a greater overall flow rate of fuel to the oil subject machine. Furthermore, the respective tubular cores of the multi-fuel hose can be used for different types of fuel, for example different kinds of liquid fuel and/or different kinds of gaseous fuel, or other consumables in liquid or gaseous form (e.g. water), and the different tubular cores can be operated simultaneously in different flow directions.

In one example, the rigid segments are provided with electrical contacts that provide an electrical path along the length of the fuel hose assembly to confirm engagement (and disengagement) of the rigid segments. The confirmation may be by means of an audible or visual indication, such as a light on the fuel dispenser's control panel.

In one example, the fuel hose assembly includes a lightning dissipation device for preventing a lightning strike. For example, a fine metal mesh may be located beneath the surface of each rigid section, and the meshes connected together by contact points between the rigid sections.

In one example, the control cord is omitted and electromagnets or solenoids are provided at both ends of each rigid segment, powered by insulated cables that pass through the rigid segments of the fuel dispenser. To compress the segments together, the solenoid is actuated to magnetically attract the rigid segments together. To reverse the process, the polarity of each opposing solenoid is reversed so that the magnetic field repels the rigid portions from each other, a fixed string is placed between each segment to limit the spacing between the rigid segments when they repel each other.

In an example, the fuel hose assembly and motorized hose drum unit are disposed in a fuel receiver (rather than a fuel dispenser), and the fuel hose assembly is connected to the fuel dispenser for a fueling operation.