FAUCET FOR WATER SUPPLY SYSTEM FOR AIRCRAFT

Abstract

A faucet for a water supply system for an aircraft includes a body portion having a water passage formed therein, and an adapter removably mounted to a discharge portion of the body portion, wherein the adapter is configured so that a mounting member is received within a casing, and the mounting member includes an orifice, a negative pressure forming chamber through which water having passed through the orifice flows, and an air passage hole communicated with the negative pressure forming chamber and mixing air taken in from an exterior of the adapter.

Claims

1-6. (canceled)

7. A faucet for a water supply system for an aircraft comprising a body portion having a water passage formed therein, and an adapter removably mounted to a discharge portion of the body portion, wherein the adapter is configured so that a mounting member is received within a casing; the mounting member comprises an orifice, a negative pressure forming chamber through which water having passed through the orifice flows, and an air passage hole communicated with the negative pressure forming chamber and mixing air taken in from an exterior of the adapter; and the adapter further comprises a dispersion member, that once diverges the water having passed through the negative pressure forming chamber and then mixes the water again, arranged within the casing and downstream of the negative pressure forming chamber.

8. The faucet for a water supply system for an aircraft according to claim 7, wherein the adapter further comprises a metal cap member having a plurality of holes on a side of the casing opposite from a side mounted to the body portion.

9. The faucet for a water supply system for an aircraft according to claim 7, wherein the adapter further comprises a strainer on a side of the casing mounted to the body portion.

10. The faucet for a water supply system for an aircraft according to claim 8, wherein the adapter further comprises a strainer on a side of the casing mounted to the body portion.

11. A lavatory unit for an aircraft comprising the faucet for a water supply system for an aircraft according to claim 7.

12. A lavatory unit for an aircraft comprising the faucet for a water supply system for an aircraft according to claim 8.

13. A galley unit for an aircraft comprising the faucet for a water supply system for an aircraft according to claim 7.

14. A galley unit for an aircraft comprising the faucet for a water supply system for an aircraft according to claim 8.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0018] FIG. 1 is a view illustrating a configuration of a faucet of a water supply system of an aircraft according to the present invention.

[0019] FIG. 2 is a view illustrating an internal configuration of an adapter 12 illustrated in FIG. 1.

[0020] FIG. 3 is a graph illustrating a water saving effect by using a faucet 10 according to the present invention.

[0021] FIG. 4 is a front view illustrating a specific example having applied the faucet 10 according to the present invention to a lavatory unit for an aircraft.

[0022] FIG. 5 is a schematic view illustrating one example of a water supply unit adopted in a lavatory for an aircraft disposed in a passenger aircraft.

DESCRIPTION OF EMBODIMENTS

[0023] FIG. 1 illustrates a configuration of a faucet for a water supply unit for an aircraft according to the present invention.

[0024] A faucet 10 is composed of a body portion 11, and an adapter 12 mounted to a discharge portion of the body portion 11.

[0025] The body portion 11 is mounted to a washbasin of a lavatory or a sink of a galley provided in an aircraft, and a water passage is formed within the body portion 11 and connected to a hydrant.

[0026] FIG. 2 is a view illustrating an inner structure of the adapter 12 illustrated in FIG. 1.

[0027] The adapter 12 adopts a structure where a mounting member 20 for mounting to the faucet 10 and an adapter body portion 22 are screw-engaged to form a casing, and an orifice 21 is formed at a center portion of the mounting member 20.

[0028] Now, as illustrated in FIG. 2, a portion upstream of the orifice 21 in the mounting member 20 is designed to have a diameter gradually narrowed down from an opening. Such shape facilitates the processing of the mounting member 20.

[0029] The shape of the portion upstream of the orifice 21 is not restricted to a shape having a gradually narrowing diameter, and can adopt other shapes such as a stepped shape.

[0030] Further, the mounting member 20 includes a negative pressure forming chamber 20a communicated with the orifice 21, and an air passage hole 20b communicated from the negative pressure forming chamber 20a to an exterior of the mounting member 20.

[0031] Now, as illustrated in FIG. 2, an opening diameter of the negative pressure forming chamber 20a is formed greater than an opening diameter of the orifice 21.

[0032] Further, a partially cut-out clearance is formed at a screw-engaged portion between the mounting member 20 and the adapter body portion 22, and the negative pressure forming chamber 20a adopts a structure to take in outer air through the air passage hole 20b by connecting the clearance with the air passage hole 20b.

[0033] On the other hand, the adapter body portion 22 has, in the interior thereof, a metal cap member 23 having a plurality of holes through which water mixed with air is discharged, and a dispersion member 24 that diverges water having passed through the negative pressure forming chamber 20a into a plurality of water flows and then merges the diverged water flows.

[0034] The dispersion member 24 adopts a configuration where a substantially conical projection 24a is formed at a center portion of one surface, and having a plurality of dispersed holes formed in a circumference of the projection 24a.

[0035] According to the above-described configuration of the dispersion member 24, the water having passed through the negative pressure forming chamber 20a of the mounting member 20 is dispersed through the projection 24a from the center portion toward the outer circumferential direction, and the water having passed through the dispersed holes is diverged into a plurality of water flows, before the plurality of diverged flows are merged again.

[0036] It is preferable to arrange a seal packing respectively between the mounting member 20 and the adapter body portion 22, and between the adapter body portion 22 and the metal cap member 23 or the dispersion member 24 received within the adapter body portion 22.

[0037] Further, it is possible to provide a strainer on an upstream side of the orifice 21 formed on the mounting member 20.

[0038] This configuration enables to prevent leakage of water from the adapter 12, and also prevent foreign substances within the water from entering the adapter 12.

[0039] According to the adapter 12 configured as above, the water flowing in from the body portion 11 of the faucet 10 passes through the orifice 21 and enters the negative pressure forming chamber 20a, and the water is mixed with the air flowing in through a communication hole 20b within the negative pressure forming chamber 20a. At this time, the negative pressure forming chamber 20a is set to negative pressure, so that the water will not flow out to the exterior through the communication hole 20b.

[0040] The water flow of water mixed with air having passed through the negative pressure forming chamber 20a is passed through the dispersed holes of the dispersion member 24, diverged into multiple water flows, and then merged again, according to which the air-mixed water flow is further stirred and mixed, before the water finally passes through the metal cap member 23 and discharged as multiple shower flows through the adapter 12.

[0041] Now, by optimizing diameters or arrangements of discharge holes formed to the metal cap member 23, the water saving effect can be achieved without changing the feeling of use of water (level of discharge of water from the faucet) with respect to the air-mixed water flow, even with a small amount of water.

[0042] Further, the adapter 12 illustrated above can be mounted to and removed from an existing faucet through screwing, without using any tool, by devising the shape of the mounting member 20.

[0043] FIG. 3 is a graph illustrating a water saving effect by using the faucet 10 according to the present invention.

[0044] As illustrated in FIG. 3 showing a graph where a horizontal axis represents water pressure (MPa) and a vertical axis represents flow rate (L/min), in a case where the faucet according to the present invention denoted by black squares (.square-solid.) is used, compared to the prior-art type faucet denoted by black circles (), a flow rate as small as approximately 0.69 L/min is realized in a case where the water pressure is 0.15 MPa, and a flow rate as small as approximately 0.87 L/min is realized in a case where the water pressure is 0.25 MPa, so that a water saving effect of 8 to 32% can be achieved within such water pressure range.

[0045] The use of such faucet realizes sufficient water saving effect while discharging water with necessary water pressure, even if the flow rate is within a small range as in the case of water supplied on an aircraft.

[0046] FIG. 4 is a front view illustrating a specific example of a case where the faucet 10 according to the present invention is applied to a lavatory unit for an aircraft.

[0047] As illustrated in FIG. 4, an aircraft lavatory unit 30 has a toilet unit 31, a washbasin unit 32 and a mirror 33 provided within a lavatory space surrounded by a plurality of panels.

[0048] The faucet 10 according to the present invention is provided above the washbasin unit 32, and an amenity storage unit storing amenities such as various expendables is formed in an inner portion of the washbasin unit 32.

[0049] Since the faucet 10 according to the present invention adopts a simple configuration of merely mounting the adapter 12 to the discharge portion of the body portion 11, as illustrated in FIG. 1, the adapter 12 can easily be mounted to, or replaced with, the discharge portion of an existing faucet.

[0050] Further, since multiple lavatory units are provided in an aircraft, the total amount of water (tank capacity) loaded in the aircraft can be reduced, so that as a result, the weight of the aircraft body during flight as a passenger aircraft can be reduced, which leads to improving fuel efficiency, and enabling to increase the number of passenger seats or increasing the load.

[0051] The embodiment of FIG. 4 illustrates an example where the water supply system including the faucet 10 according to the present invention is applied to a lavatory unit of an aircraft, but the faucet according to the present invention can also be applied, for example, to a water supply system or the like of a sink provided within a galley of an aircraft for serving meals.

REFERENCE SIGNS LIST

[0052] 10 Faucet [0053] 11 Body portion [0054] 12 Adapter [0055] 20 Mounting member [0056] 20a Negative pressure forming chamber [0057] 20b Air passage hole [0058] 21 Orifice [0059] 22 Adapter body portion [0060] 23 Metal cap member [0061] 24 Dispersion member [0062] 30 Lavatory unit