The present invention relates to multi-hulled water craft and specifically relates to the location of a movable hull.
Marine vessels including multiple hulls can include suspension for locating and controlling the position of at least one of the hulls relative to the chassis or body portion. For example, U.S. Pat. No. 7,314,014 discloses a water craft having a body portion suspended above four hulls, each hull being located relative to the body portion by a single wishbone suspension linkage arrangement.
U.S. Pat. No. 5,228,404 discloses a trimaran where the chassis is supported above three hulls, each being movable relative to the chassis. The three hulls comprise a left hull, a right hull and a rear central hull, all three hulls being interconnected by a lateral bar about which they are individually pivoted. The rear centre hull has two laterally spaced rearward trailing arms and a forwardly spaced central trailing arm, all three trailing arms being parallel and having substantially the same length to maintain the rear centre hull horizontal relative to the chassis, since the rear centre hull also contains the propulsion means for the vessel. The front and rear of each of the laterally spaced (left and right) side hulls has a respective support arrangement. Each front and rear support arrangement comprises a long lateral arm between the chassis and the respective side hull and a short lateral arm between the chassis and the centre of the long lateral arm. The chassis end of the long lateral arm can slide along lateral tracks on the chassis acting against a spring and damper, the respective arrangement thereby providing resilient, damped support of the chassis above the respective end of the respective hull together with maintaining the lateral location of the side hull under the chassis mounting position of the short lateral arm.
U.S. Pat. No. 9,272,753 discloses a catamaran having a suspension geometry of a front leading arm and a rear slider for each hull to provide the required lateral, longitudinal, yaw and roll location of the respective hull relative to the chassis or body portion, leaving the hull free to move in the heave and pitch modes relative to the chassis. Heave motions relative to the chassis of the left hull in an opposition direction to the right hull is the roll mode of the suspension system. Similarly pitch motions relative to the chassis of the left hull in an opposite direction to the right hull is the warp mode of the suspension system.
However with such marine vessels having a chassis or body portion at least partially suspended relative to multiple hulls, regardless of whether the chassis engages the water or not, there is a design compromise in the width of the vessel between the hulls being laterally spaced wide apart for passive roll stiffness and the hulls being laterally spaced close together to make the vessel footprint narrow for negotiating confined spaces such as ports or marinas and/or for transportation on a trailer.
The trimaran disclosed in U.S. Pat. No. 4,730,570 has left and right hulls mounted on cross beams that can be moved laterally to vary the beam (i.e. the track or width) of the vessel, but without changing vessel height and without providing for any suspension motion to accommodate resilient supports.
The catamaran in U.S. Pat. No. 5,277,142 uses pairs of upper and lower unequal length lateral swing arms to reduce the width or beam of the vessel by swinging the left and right hulls under the chassis, which raises the chassis while reducing the track or lateral spacing between the side hulls.
In U.S. Pat. No. 8,408,155 the left and right hulls are also not able to move resiliently relative to the chassis, but are mounted to the chassis by swing arms to enable the chassis to be raised to improve the clearance of the chassis to the waves. However, the lateral spacing between the hulls is decreased when the chassis is raised, which is an undesirable combination for stability. Chinese registered utility model number 201999173 discloses a similar arrangement where each side hull of a catamaran is fixed to a swing arm that rotates relative to the chassis to both raise the chassis and decrease the lateral spacing between the hulls, or conversely to lower the chassis and increase the lateral spacing of the hulls and the vessel width. Both of these two inventions lower the vessel centre of gravity and simultaneously widen the spacing between the left and right hulls for improved stability when operating at speed. However vessel speed can be limited by wave impacts, so the rougher the sea state the larger the requirement for the height under the chassis.
Japanese patent application publication number 2002193181 discloses a planing type high speed vessel which has a chassis or body portion supported above hydrofoils resiliently mounted on the ends of extending rams or linkages to enable the height of the body portion above the hydrofoils to be increased. As the height of the body portion is increased relative to the hydrofoils, the width (i.e. lateral spacing) between the hydrofoils also increases. However there is only one suspension locating linkage for each hydrofoil to locate it relative to the body portion which does not provide a strong control of the yaw of the hydrofoil relative to the body portion.
According to a first aspect of the invention there is provided a suspension system for a water craft, the water craft including a chassis and at least a first hull and a second hull, the suspension system including a first hull locating arrangement for at least partially constraining the first hull in a lateral, a yaw, a roll and a longitudinal direction relative to the chassis; the first hull locating arrangement comprising a first, a second, a third and a fourth link arranged to directly or indirectly connect between the hull and the chassis; the first, second and third links each extending in at least a lateral direction relative to the chassis and contributing to a lateral constraint on the first hull relative to the chassis, the second link being longitudinally spaced from the first link relative to the chassis to contribute to a hull yaw constraint on the first hull relative to the chassis, the third link being vertically spaced from the first and/or second link to contribute to a hull roll constraint on the first hull relative to the chassis, the fourth link extending in at least a longitudinal direction relative to the chassis to contribute to a longitudinal constraint on the first hull relative to the chassis.
Also disclosed is a suspension system for a water craft, the water craft including a chassis and at least a first hull and a second hull, the suspension system including a first hull locating arrangement for at least partially constraining the first hull in a lateral, a yaw, a roll and a longitudinal direction relative to the chassis, the first hull locating arrangement comprising a first, a second, a third and a fourth link, the first, second and third links each extending in at least a lateral direction relative to the chassis, the second link being longitudinally spaced from the first link relative to the chassis, the third link being vertically spaced from the first and/or second link, the fourth link extending in at least a longitudinal direction relative to the chassis.
Each of said respective first, second, third and fourth links may be connected to the chassis by a respective chassis joint and may be connected directly or indirectly to the hull by a respective hull joint. The first and second hull joints may be longitudinally spaced. The first and second chassis joints may be longitudinally spaced. Spacing the first link longitudinally from the second link assists in providing a hull yaw constraint on the hull relative to the chassis. If the third link is vertically spaced from the first link then the third hull joint may be vertically spaced from the first hull joint and the third chassis joint may be vertically spaced from the first chassis joint. If the third link is vertically spaced from the second link then the third hull joint may be vertically spaced from the second hull joint and the third chassis joint may be vertically spaced from the second chassis joint. Spacing the third link vertically from the first and/or second link assists in providing a hull roll constraint on the hull relative to the chassis. Hull yaw is yaw of an individual hull relative to the body, as opposed to body yaw which is yaw of the body relative to the average position of all of the hulls. Similarly hull roll is roll of an individual hull relative to the body, as opposed to body roll which is effectively heave of the first hull in an opposite direction to the second hull relative to the body.
As the first, second and third links each extend in at least a lateral direction relative to the chassis, they contribute to providing a lateral constraint on the hull relative to the chassis. As the fourth link extends in at least a longitudinal direction relative to the chassis, it assists in providing a longitudinal constraint on the hull relative to the chassis. Together the first, second, third and fourth links may provide yaw, roll, lateral and longitudinal constraints on the hull relative to the chassis such that pitch and heave motions of the first hull relative to the chassis, at least within an operating range, are not constrained by the first hull locating arrangement.
The suspension system may further include variable length supports or support arrangements between the chassis and the at least two hulls for providing at least partial support of the chassis relative to the at least two hulls. At least one of said variable length supports may include a support cylinder, air spring and/or mechanical spring such as a coil spring. Alternatively or additionally, at least one of said variable length supports may be connected between the chassis and the first hull. Alternatively or additionally, at least one of said variable length supports may be connected between the chassis and one of the first, second, third or fourth links. Alternatively or additionally, at least one of said support arrangements may be connected between the first hull and one of the first, second, third or fourth links.
The variable length supports may include modal supports, interconnected to provide different stiffness rates between at least two suspension modes, such as providing roll stiffness without providing warp stiffness, or providing different pitch and heave stiffness rates. Alternatively or additionally, the variable length supports may be interconnected to facilitate active control of one or more suspension modes from roll, pitch and heave. Alternatively or additionally the variable length supports, be they independent or interconnected, may be controlled to maintain chassis attitude and/or height. Alternatively or additionally at least a front left, a front right, a back left and a back right variable length support may be provided and controlled to actively adjust at least one of the roll attitude of the chassis, the pitch attitude of the chassis, the height of the chassis relative to the hulls or the warp forces in the variable length supports.
At least one of said chassis or hull joints may provide substantially linear motion constraints and permit at least limited rotational motion. Each of said four links may include a chassis joint and a hull joint or alternatively two chassis joints of the first, second, third or fourth chassis joints may be combined or the fourth hull joint and one of the first, second or third hull joints may be combined.
The fourth hull joint of the fourth link may be fixed to one of the first, second or third links or the chassis joint of one of the first, second or third links may be fixed to the fourth link. At least one of the first, second and third hull joints may connect the respective link to an up-stand projecting above the first hull. The, or each up-stand projecting above the first hull may be fixed to the first hull.
The fourth link may be positioned nearer to the bow of the first hull than the stern of the first hull, in which case the hull joint of the fourth link may preferably be forward of the chassis joint of the fourth link. Alternatively, the fourth link may be positioned nearer to the stern of the first hull than the bow of the first hull, in which case the hull joint of the fourth link may preferably be rearward of the chassis joint of the fourth link. If the fourth chassis joint is above the fourth hull joint at a ride height, such arrangements can provide anti-dive or anti-squat properties.
The fourth link may have a primary axis through the fourth chassis joint and the fourth hull joint. The fourth link may further include a length adjustment device for adjusting the length of the fourth link between the fourth chassis joint and the fourth hull joint, or the fourth link may be length adjustable using a length adjustment device such that a straight line distance between the fourth chassis joint and the fourth hull joint may be adjusted. The length adjustment device may be adjustable between a wide hull spacing position and a narrow hull spacing position where in the wide hull spacing position the first hull is spaced further away from a centre-line of the chassis than in the narrow hull spacing position. In the wide position the length of the length adjustment device may be less than in the narrow position. Alternatively, in the wide position, the length of the length adjustment device may be greater than in the narrow position. In the wide hull spacing position at least one of the first, second or third links may also extend in a longitudinal direction relative to the chassis. Said at least one of the first, second or third links that also extends in a longitudinal direction relative to the chassis may extend further in a lateral direction than in a longitudinal direction. Alternatively or additionally, in the narrow hull spacing position at least one of the first, second or third links may also extend in a longitudinal direction relative to the chassis. Said at least one of the first, second or third links that also extends in a longitudinal direction relative to the chassis may extend further in a lateral direction than in a longitudinal direction.
First supports may be arranged between the chassis and the first hull or any of the first, second, third or fourth links, each support being effectively connected to the chassis by a chassis mounting point and effectively connected to the hull by a hull mounting point on the first hull or on any of the first, second third or fourth links, the chassis and hull mounting points being arranged such that when adjusting the length adjustment device of the fourth link from the wide hull spacing position to the narrow hull spacing position, an inclination of each support is increased, reducing a vertical support force relative to the chassis so that a height of the chassis relative to the hulls is reduced. For example, the chassis mounting point and the hull mounting point of each support can be chosen such that as the vessel width is reduced from that of the wide hull spacing position to the narrow hull spacing position, each support becomes inclined or further inclined, providing less vertical support force so that the chassis is lowered relative to the hulls. Preferably, in the narrow hull spacing position, the chassis is lowered to a minimum or bump stop contacting height. Alternatively the chassis height may be reduced by at least 10 percent of a total suspension travel distance.
Alternatively or additionally, the fourth link may also extend in a lateral direction relative to the chassis. However in at least a wide hull spacing position, the fourth link may extend further in a longitudinal direction than in a lateral direction. Alternatively, the fourth link may extend further in a lateral direction than in a longitudinal direction, particularly, although not exclusively, when the first link extends in a longitudinal direction in addition to extending in a lateral direction. For example, the first link and the fourth link may form a wishbone shape and may be rigidly connected to each other to form a wishbone.
The fourth link of the first hull locating arrangement may be length adjustable. Adjusting a length of the fourth link may change a lateral spacing between the first hull and the second hull. Alternatively or additionally, adjusting a length of the fourth link may displace the first hull laterally and longitudinally relative to the chassis.
The suspension system may further include at least a first forward cylinder and a first rearward cylinder for providing support and/or damping forces between the first hull and the chassis. The first forward cylinder may be positioned closer to a bow portion of the first hull than the first rearward cylinder. Alternatively or additionally, the first forward cylinder may be connected between the chassis and the first link. The first forward cylinder may be connected between the chassis and a hull joint of the first link, or connected between the first hull and a chassis joint of the first link.
The first rearward cylinder may be connected between the chassis and the second link. Attractively or additionally, the first rearward cylinder may be connected between the chassis and a hull joint of the second link, or connected between the first hull and a chassis joint of the second link.
Alternatively, the suspension system may further include at least a first additional cylinder for providing support and/or damping forces between the first hull and the chassis. The first additional cylinder may be longitudinally positioned between the first forward cylinder and the first rearward cylinder. The third link may be longitudinally spaced between the first and second links.
The first additional cylinder may be connected between the chassis and the third link or the first additional cylinder may be connected between the chassis and a hull joint of the third link, or connected between the first hull and a chassis joint of the third link.
Alternatively, the fourth link may be longitudinally spaced between the first and second links. The first additional cylinder may be connected between the chassis and the fourth link. Alternatively, the first additional cylinder is connected between the chassis and a hull joint of the fourth link, or connected between the first hull and a chassis joint of the fourth link.
The suspension system may further include at least a second forward cylinder and a second rearward cylinder for providing support and/or damping forces between the second hull and the chassis.
The suspension system may further include a first forward independent support, a first rearward independent support, a second forward independent support and a second rearward independent support. The first forward, first rearward, second forward and second rearward cylinders may provide damping and/or attitude adjustment forces; and the first forward independent support, the first rearward independent support, the second forward independent support and the second rearward independent support may provide at least a portion of the support of the chassis relative to the first and second hulls. Alternatively, the first forward, first rearward, second forward and second rearward cylinders may be modal supports, providing a portion of the support of the chassis relative to the first and second hulls, being interconnected to provide different stiffness in at least two of a roll, pitch, heave and/or warp suspension modes; and the first forward independent support, the first rearward independent support, the second forward independent support and the second rearward independent support may provide a portion of the support of the chassis relative to the first and second hulls.
Alternatively, the first forward cylinder, first rearward cylinder, second forward cylinder and second rearward cylinder may each be an independent support.
The independent supports may be controlled to adjust loads or displacements of the supports in at least one of a roll, pitch, heave and/or warp suspension mode.
Alternatively, the first forward cylinder, first rearward cylinder, second forward cylinder and second rearward cylinder may each be a modal support, each modal support being directly or indirectly interconnected to at least one other modal support to thereby provide different stiffness in at least two of a roll, pitch, heave and/or warp suspension modes. The modal supports may be controlled to adjust loads or displacements of the supports in at least one of the roll, pitch, heave and/or warp suspension mode.
Another aspect of the present invention provides a water craft including the suspension system as described above.
Another aspect of the present invention provides a multi-hulled vessel or water craft including a chassis, two moveable hulls and a suspension system, the suspension system including a respective hull locating arrangement for each respective moveable hull to provide linear and rotational constraints on motion of the hull relative to the chassis (e.g. linearly in a substantially longitudinal direction and in a substantially lateral direction relative the chassis and rotationally about the roll and yaw axis of each hull), wherein one or each of the respective hull locating arrangements comprises four links, each link being connected directly or indirectly between the respective hull and the chassis, the four links consisting of a first, second, third and fourth link, each link having a body joint between the link and the body and a hull joint between the link and the hull or one of the other of the four links, the first and second links each extending in at least a lateral direction relative to the chassis, the second link being longitudinally spaced from the first link relative to the chassis, at least the fourth link extending in at least a longitudinal direction, the fourth link providing a longitudinal constraint on motion of the respective hull relative to the chassis, the first second and third links adding a lateral, a yaw and a roll constraint on motion of the respective hull relative to the chassis, such that pitch and heave motions of the respective hull relative to the chassis are not constrained.
It will be convenient to further describe the invention by reference to the accompanying drawings which illustrate aspects of the invention. Other embodiments of the invention are possible and consequently particularity of the accompanying drawings is not to be understood as superseding the generality of the preceding description of the invention.
In the drawings:
Referring initially to
Throughout the specification where the term chassis is used it is referring to the structure to which the hulls are located by the suspension system and can be interchangeable with the term body portion. The chassis can be a simple platform or include gunwales, a passenger cabin, cargo area. For example, as in automotive use, the chassis can be a ladder frame, or it can combine a ladder frame with a fixed cabin where the suspension loads are primarily input into the ladder frame, or it can be a monocoque where the suspension loads are input into a shell structure including the cabin. The water craft is shown at ride height, i.e. somewhere between the maximum and minimum height of the chassis above the hulls, typically between 30 and 70% of that total travel between maximum and minimum height.
Each hull 3 or 4 is connected to the chassis 2 by a locating arrangement comprising four links 10, 11, 12 and 13 or 20, 21, 22 and 23. The first link, which in this example is the front link 10 is connected to the hull at joint 10a and to the chassis at joint 10b. Throughout this specification, where the term joint is used it may be referring to a ball joint or other spherical joint, a resilient bushing or any other form of joint that permits at least limited rotation about at least one, two or all three mutually perpendicular axes and provides a constraint on linear motion in at least two or all three mutually perpendicular directions.
The second link, which in this example is the back link 11 is connected to the hull (in this example, via an up-stand 14 which is rigidly connected to the hull) at joint 11a and to the chassis at joint 11b. The longitudinal spacing of the front and back links 10 and 11 provides some yaw location of the hull relative to the chassis. For example, when the other links are providing stability through other constraints such as roll and longitudinal constraints on motion of the hull relative to the chassis, then the front and back links are able to provide at least some of the forces required to react yaw and lateral motions of the hull relative to the chassis. So the first and second links (the front and back links 10 and 11 in this example) at least assist in providing a yaw constraint on the hull relative to the chassis.
The third link, which in this example is the upper link 12 is connected to the hull at joint 12a (in this example on the same up-stand 14 as the back link 11) and to the chassis at joint 12b. The vertical spacing of the upper link from one or both of the front and back links provides some roll location of the hull 3 (substantially about a longitudinal or roll axis of the hull). For example, when the other links are providing stability through other constraints such as yaw, longitudinal and some lateral constraints on motion of the hull relative to the chassis, then the third link together with at least one of the front and back links are able to provide at least some of the forces required to react roll and lateral motions of the hull relative to the chassis. So the third link (the upper link 12 in this example) assists in providing a roll constraint on the hull relative to the chassis.
If the first, second and third links (in this example, the front link 10, back link 11 and upper link 12) are all of equal length, are all oriented laterally in plan view (i.e. when viewed from above) and are all oriented parallel to each other in end view (such as front view) then the hull will not roll about its primary (longitudinal) axis nor yaw relative to the chassis if the hull moves in heave mode only. Through the heave stroke of the hull there will be some lateral motion of the hull relative to the chassis, but that can be minimised by the use of long links (i.e. maximising the distance between the hull and chassis joints of each link) and/or having the links oriented horizontally at a preferred ride height or at mid stroke.
The fourth link 13 is a leading arm in this example, connected to the hull 3 at joint 13a and to the chassis at joint 13b and runs in an at least partially longitudinal direction relative to the chassis. The fourth link helps to define the longitudinal position of the hull relative to the chassis. For example, when the other links are providing stability through other constraints such as yaw, roll and lateral constraints on motion of the hull relative to the chassis, then the fourth link is able to provide at least some of the forces required to react longitudinal motions of the hull relative to the chassis. So the fourth link at least assists in providing a longitudinal constraint on the hull relative to the chassis. In this example, the fourth link 14 provides a substantially longitudinal constraint between the hull and the chassis. The use of such a forward positioned leading arm can be beneficial as it can be angled upwards as it runs backwards, i.e. the chassis joint 13b can be higher than the hull joint 13a at ride height, to assist in control of the pitch attitude of the chassis as the water craft slows or accelerates in a fore-aft direction. The four links 10, 11, 12 and 13 of the left hull locating arrangement together provide lateral, yaw, roll and longitudinal constraints on the motion of the left hull 3 relative to the chassis 2, permitting heave and pitch motions of the hull relative to the chassis. The front link 20, back link 21, upper link 22 and fourth link 23 between the right hull 4 and the body or chassis 2 similarly form a right hull locating arrangement constraining lateral, yaw roll and longitudinal motions of the hull 4 relative to the chassis 2, while permitting heave and pitch motions of the hull relative to the chassis. The back links 21 and 22 are connected to an up-stand 24 that is rigidly connected to the hull. This helps provide a vertical spacing between the upper and lower back links 21 and 22 with roll torques on the hull being reacted by compressive and tensile forces in the upper and lower links and the vertical spacing between said links.
The left leading arm 13 and the right leading arm 23 can be rigid links. Alternatively, as shown in the
The body or chassis 2 is supported above each of the left and right hulls 3 and 4 by longitudinally spaced supports such as the front left support or ram 17, back left support or ram 18, front right support or ram 27 and back right support or ram 28. The supports 17, 18, 27, and 28 are shown as rams and can be or include any known resilient or controllable support such as hydraulic rams, electromagnetic actuators, air springs or mechanical springs such as coil springs. Although the supports 17, 18, 27 and 28 are shown acting directly onto the hulls 3 or 4, they can be positioned between the body or chassis 2 and any of the four links or indeed additional links arranged to provide transmission of support forces ideally without providing additional locational constraints.
The water craft 1 is shown in plan view in
A chassis supported above four variable length supports can have four modes of motion: roll, pitch, heave and warp. As mentioned above, the four links locating each hull permit heave (vertical) and pitch motions of each hull relative to the chassis. Pitch motions of the left and right hulls 3 and 4 in opposite directions as shown in
Conversely, heave motions of the left and right hulls 3 and 4 in opposite directions provides roll of the body or chassis 2 relative the hulls 3 and 4 (which is different from a roll motion of an individual hull relative to the chassis, i.e. a hull rotating about a longitudinal axis while the remainder of the water craft is fixed for example). In
In all of the drawings so far (i.e.
Rather than change between two positions, it is possible alternatively to adjust the track of the hulls in proportion to the ride height of the vessel. Many variations are possible such as adjusting the track of the hulls in proportion to a sensed height of a body portion or chassis centre of mass for example. Or the sea state may be used to determine the track, although it is more usual to use sea state to determine ride height and then in turn the ride height can optionally be used to determine the track.
In the example geometry shown in
In
As can be best seen in
In all of the disclosed geometry arrangements of four links herein, each hull is able to heave and pitch relative to the chassis, providing the left and right hulls of a catamaran incorporating such a suspension system with the ability to together move relative to the chassis in the modes of pitch, heave and warp, with the chassis being able to roll relative to the average vertical position of the left and right hulls. The waterline 34 is indicated in
The supports (such as for example 17, 18, 27, 28 in
Modifications and variations as would be apparent to a skilled addressee are deemed to be within the scope of the present invention.
Number | Date | Country | Kind |
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2016900811 | Mar 2016 | AU | national |
2016902629 | Jul 2016 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2017/050187 | 3/3/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/147658 | 9/8/2017 | WO | A |
Number | Name | Date | Kind |
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4730570 | Harris | Mar 1988 | A |
5228404 | Gibbs | Jul 1993 | A |
5277142 | Connor | Jan 1994 | A |
6176190 | Ozga | Jan 2001 | B1 |
7314014 | Heyring et al. | Jan 2008 | B2 |
7316595 | von Wolske | Jan 2008 | B2 |
8408155 | Sancoff et al. | Apr 2013 | B2 |
9272753 | Heyring | Mar 2016 | B2 |
20100000454 | Grenestedt | Jan 2010 | A1 |
20130213288 | Hall | Aug 2013 | A1 |
Number | Date | Country |
---|---|---|
201999173 | Oct 2011 | CN |
2450192 | Sep 1980 | FR |
2397556 | Jul 2004 | GB |
2002193181 | Jul 2002 | JP |
2013126583 | Aug 2013 | WO |
Entry |
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International Search Report for Application No. PCT/AU2017/050187 dated Mar. 31, 2017 (3 pages). |
Number | Date | Country | |
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20190092435 A1 | Mar 2019 | US |