WATER PORT CLOSURE ASSEMBLY

A fill port assembly comprising: a housing having an opening therethrough; a fill port located in and extending through the opening defining a flow passage through the fill port from a first end to a second end, the flow passage having an axis defined between the first end and the second end; and a closure mechanism moveable between an open position in which the flow channel is open and allows fluid flow therethrough and a closed position in which the flow channel is closed and prevents fluid flow therethrough, wherein the closure mechanism comprises: a cap attached at a first side of the cap to a first side of the housing via a hinge, the cap pivotable about the hinge between an open position with respect to the fill port and a closed position to close the second end of the fill port.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to, and the benefit of, EP Patent Application No. 23461506.0, filed Jan. 26, 2023 and titled “WATER PORT CLOSURE ASSEMBLY,” which is incorporated by reference herein in its entirety for all purposes.

FIELD

The present disclosure is concerned with providing a closure assembly for ports in a water system, such as the fill and overflow ports of a water system. The water system can, for example, be a system for providing potable or fresh water in an aircraft.

BACKGROUND

Water systems often include a tank or storage vessel to store water which can then be plumbed to other parts of the system to provide water to different parts of the system from the storage tank/vessel. The tank will need to be periodically re-filled. Typically, the tank is provided with a fill port to which a fill line, connected to a source of water, is connected for re-filling the tank from the source. The tank may also be provided with an overflow or overfill line via which water can exit the tank if the tank is overfilled. The overflow water exits from an overflow port on the tank. During the tank filling process, the fill port, and, where present, the overflow port, will be open. In some applications, the ports are left open after filling. The ports may be provided in an operating panel that is covered by a door or panel when not in use. In certain environments, e.g. where the tank is subjected to movement or vibration or in environments where debris or contaminants exits which should not be allowed to get into the tank, a closure or cap assembly is provided at the ports to close the port(s) when not being filled. In an arrangement with a fill port and an overflow port, each port may be provided with its own cap or closure or, alternatively, a single closure can be provided that covers both ports, when closed. Such assemblies may be used, for example, in aircraft. An aircraft typically has water stations in the cabin for dispensing drinking water during flight. The aircraft has a storage tank filled with potable water and plumbing to provide water from the tank to the stations as required. The tank is re-filled between flights by ground crew, by connecting an external source of water, e.g. a water truck, to the tank via a hose connected to the fill line attached to the fill port.

Whilst existing closure arrangements are effective in closing the ports, they are typically hinged relative to the ports in such a way that they require a large area around the ports to allow them to open and close. Typically, an arm or lever is attached to the caps and is moved in a large arc to open the caps. In environments where space is limited e.g. in aircraft, this is undesirable and there is a need for an improved port closure assembly that provides effective closure but also allows the closure to be opened and closed within a limited space. In addition, repeated opening and closing of the closure components about a hinge causes wear and means that the parts need to be replaced long before their life would otherwise expire.

SUMMARY

According to the disclosure, there is provided a fill port assembly comprising: a housing having an opening therethrough; a fill port located in and extending through the opening defining a flow passage through the fill port from a first end to a second end, the flow passage having an axis defined between the first end and the second end; and a closure mechanism moveable between an open position in which the flow channel is open and allows fluid flow therethrough and a closed position in which the flow channel is closed and prevents fluid flow therethrough, wherein the closure mechanism comprises: a cap attached at a first side of the cap to a first side of the housing via a hinge, the cap pivotable about the hinge between an open position with respect to the fill port and a closed position to close the second end of the fill port, and a catch assembly provided between a second side of the cap, opposite the first side, and a second side of the housing, opposite the first side, to releasably secure the cap in the closed position, wherein the catch assembly comprises a spring latch part secured in a channel at the second side of the housing, the spring latch part having first and second end pins and a spring between the first and second end pins, the spring biased to extend the first and second end pins beyond the respective ends of the channel, the catch assembly further comprising opposing first and second catch arms extending from the second side of the cap arranged to cooperate respectively with the first and second ends of the spring latch part as the cap is pivoted about the hinge to the closed position, the first and second catch arms each having a respective inwardly facing recess in which the respective ends of the spring latch part are received when the cap is moved to the closed position.

Also provided is a port assembly comprising a fluid port having a fluid flow channel defined along an axis and fluid opening at an end of the fluid flow channel, and a closure assembly as defined above.

DETAILED DESCRIPTION

By way of background, an example of a known port closure assembly50will first be described, with reference toFIGS.1,2A and2B.

In this assembly, a fill port1and an overflow port2are provided in a housing10. These will be in fluid connection at a first end11,21with the storage tank or other vessel to be filled via the fill port. The second end12of the fill port1is provided with a respective fitting31configured to be fluidly connected to a fill line (not shown) when the tank is being filled. The second end22of the overflow port2is provided with a fitting configured to be fluidly connected to an overflow line (not shown). A cap3is provided to cover the second ends12,22of the fill and overflow ports in the closed state. In the example shown, a single cap is provided that covers both ports1,2as this simplifies the closing operation by the user and reduces the risk of a port being inadvertently left open after filling. Other known assemblies have a separate cap for each port.

The cap3is mounted to the assembly housing10by a hinge arrangement4adjacent the second ends of the ports, and is provided with a lever and latch mechanism5to open and close the cap3. The inner surface of the cap, that comes into contact with the second end of the port(s) when closed, is preferably provided with a seal6. An additional seal, such as an O-ring seal7, may also be provided around the second end of the port(s). The inner surface of the cap may be formed with respective plugs or protrusions41,42arranged to fit into the port fittings when the cap is closed.

In the example, the latch and lever mechanism includes a lever15having a lever body151, a lever end152and a latch end153. When the cap3is in the closed position, the lever body151lies across the outer surface of the cap, essentially flat against the cap, with the lever end152adjacent the hinge4. The latch end153includes a catch or claw154that secures in a recess or detent155on the side of the housing opposite the hinge4. The closed position is shown inFIG.2A.

To open the cap3, the lever end152first needs to be lifted away from the cap, in the direction of arrow A inFIG.2Ato cause the latch end153to move the claw154out of engagement with the detent155. The lever15is then moved in an arc movement (arrow B inFIG.2B) about the hinge4. As the latch end of the lever is attached to the cap3(e.g. by a pin8), the movement of the latch causes corresponding movement of the cap3about the hinge4to move the cap3out of engagement with the second end of the port(s) (FIG.2B). In an example, not shown, where each port has its own cap, the opening motion would be similar for each cap3.

To close the cap3, the lever15is then moved in an arc relative to the housing (arrow C inFIG.2B) opposite to the opening direction B, moving the lever and the cap about the hinge4to close over the port and to bring the latch end154into engagement with the detent155. The lever is then brought down (arrow D) towards the outer surface of the cap3to the original position, essentially flat against the cap3(FIG.2A) and the latch end locks behind the detent.

As can be seen from, in particular,FIG.2B, the arcuate motion of the lever and the cap defines a large range of movement relative to the size of the overall assembly and would require a large area above the ports to allow the cap to be opened and closed.

Further, because the lever and the detent of the catch with which it engages have a tight fit, there is a high frictional force between the parts and the repeated movement of the lever about the hinge also causes wear of the closure parts including the hinge part of the housing. If the engagement between the lever and the detent becomes loose, there is a risk of the cap inadvertently opening. As the detent is formed integrally with the housing, which is a fully machined part, such a housing is expensive and time consuming to manufacture.

The present disclosure provides an improved closure assembly that requires less space to open and close the cap(s), and is smaller and simpler and less expensive to manufacture. An example will be described with reference toFIGS.3to6.

In the same way as shown inFIGS.1and2(and again inFIG.6A), the closure assembly50′ of the disclosure, and example of which is shown inFIG.6B, is provided for a fill port100and an overflow port200provided in a housing10′. As in the example described above, the first end101of the fill port and the first end201of the overflow are configured to fluidly connect to the storage tank. The fittings110and210at the second ends of the ports are configured to, respectively, fluidly connect to the fill line and the overflow line (not shown) during filling. A flow passage111,211extends from the fittings, through the port, to the first ends. A cap300is attached to the housing10′ via a hinge400, the hinge being provided by an upstanding hinge flange410at one side10aof the housing10′ which forms a hinge400with two opposing hinge arms310a,310bextending from one side300aof the cap300. The height of the hinge flange and the configuration of the hinge is such that the cap lies flat across the ports to close the ports in a closed position in the same way as the cap of a known assembly such as shown inFIG.6B. A catch assembly500is provided to lock the cap300in the closed position relative to the housing10′ and the ports. The closure assembly of this disclosure is, however, different to the known assembly described above. Rather than the closure requiring a large radius lever to open and close the fill ports, the closure is formed with a releasable spring catch between the cap and the housing as will be described further below.

The examples shown in the drawings and described below all have two ports and a single cap that covers both ports. This is, however, just one example and the principles of the assembly of the invention can also be applied to an assembly only having a single port and/or having multiple ports each with its one individual cap.

Instead of the lever/latch mechanism, the closure of the present disclosure comprises a spring latch part700that is located in a channel800formed in a catch flange440on the side10bof the housing opposite (with respect to the location of the ports extending through the housing10′) the side of the hinge flange410of the housing10′. A catch600on the cap300at side300bopposite the hinge side300aof the cap, forms a locking engagement with the spring latch part when the cap is closed. The locking engagement is released by a user manually opening the cap.

As best seen inFIGS.3A,3B,4A,4B,5A and5B, the spring latch part700comprises a spring710mounted in a spring latch part body720having an axis X between a first end721and a second end722, the spring extending along the axis. The spring latch part also comprises a first ball pin731at a first end711of the spring710and a second ball pin732at a second, opposite end712of the spring, the spring force being such as to bias the ball pins to extend from the respective first end and second end of the spring latch part body, the ball pins being axially moveable relative to the spring latch part body with extension (direction L) and compression (direction L′) of the spring. The ends731a,732aof the ball pins extending from the spring latch part body are rounded.

The position and height of the catch flange410is such that the position of the channel800and, accordingly the spring latch part700located in the channel aligns with the catch600formed on the cap of the fill port. The axial dimension of the channel in the catch flange matches the axial dimension between two opposing arms610a,610bof the catch. The arms of the catch are provided with recesses612a,612bconfigured to receive the ball pins731,732extending from the spring latch part body and the channel when the cap is closed and the catch fits over the catch flange of the housing. In the closed position, therefore, the arms of the catch are located either side of the channel in the catch flange with the recesses aligned with the channel, the ball pins are biased by the spring to extend out of the channel beyond the axial ends of the catch flange and to extend into the corresponding recess of the catch of the closed cap to lock the cap in the closed position. This is shown inFIG.4A.

To open the cap, the cap is lifted in the opening direction (Direction B′) which causes the edges E of the recesses612a,612b,as the latch is lifted with the cap, to press against the ball pins against the biasing force of the spring. This pushes the ball pins axially inwards (direction L′) into the channel, compressing the spring. The ball pins no longer engage in the recesses and so the cap is free to open, as shown inFIG.4B. Once the cap catch has passed the ball pins, the spring relaxes again so that the ball pins extend again out of the channel.

To re-close and lock the cap, the cap is closed (opposite to direction C) causing the edges E of the recesses in the catch arms to ride against and press, against the spring force, the rounded ends of the ball pins. As the recesses align with the ball pins, the ball pins are able, under the force of the spring, to move in direction L into the recesses where they lock until a manual opening force is applied by the user.

The closing force of the assembly is adjusted by the force of the spring710. This means that different opening forces can be selected depending on the situation in which the assembly is used, e.g. setting a higher opening force to avoid accidental opening in high vibrational environments, but also setting the force low enough to allow a user to manually open the cap.

In the example shown, to better secure the spring latch part in the channel of the flange, the outer surface of the spring latch part body may be provided with surface features e.g. an external thread900to engage with corresponding features/threads in the channel. The allows for simple and reliable assembly of the part and means that the part can be easily removed and exchanged in the event of wear or damage.

A particular advantage of the assembly according to this disclosure is that the spring latch part can be manufactured using additive manufacturing (AM) which enables relative complex structures to be made easily, quickly and inexpensively. Holes90may be formed in the body, through the thread900, for removal of an additive powder after finishing the AM process. These same holes90can, then, after assembly, be used for injection of lubricant into body. This can prevent dirt and other contaminants getting into the part and can extend the lifetime of the part. The parts can be manufactured, for example, using steel powder. The use of AM reduces assembly and machining time and cost resulting in a less expensive assembly. The risk of failure during assembly is also reduced. As the part has relatively small dimensions, a normal machine manufacture and assembly could result in damage to the part. This is avoided when using AM.

As can be seen by comparingFIGS.5A and5B, in the known latch/lever assembly (FIG.5A) all of the force F of the catch acts on a single point of the assembly which can lead to wear. In contrast, in the assembly of this disclosure, particularly when made using AM, the force is distributed across two points P1, P2of contact which results in reduced overall wear.

As mentioned above, the closure assembly can also be used with an assembly having a single port or with an assembly having several ports each with an individual cap and closure assembly. Such embodiments also fall within the scope of the invention as defined by the claims.