The present invention relates to a mooring anchor for a mooring target such as a floating photovoltaic power system, an aquaculture cage, a floating pier, or a water sports facility for, for example, canoeing.
Mooring anchors are typically heavy objects such as concrete blocks. Many anchors, each fastened to a basal end of a mooring line, are installed at the water bottom to surround the mooring position of a mooring target. The anchors, located near the mooring target, mainly receive upward tensile forces when the mooring target moves on the water surface. Thus, the anchors are installed to have sufficiently high tensile resistance.
Further, anchors located near a mooring target with short mooring lines are less responsive to changes in the water level, and also can have the mooring lines under rapidly increasing tensile forces when the mooring target moves. The mooring lines or the mooring target may receive strong impact, or the mooring lines may be broken.
To avoid impact on or breakage of a mooring line, a structure described in Patent Literature 1 includes a sinker as a heavy object between an anchor and a mooring target.
However, the sinker moves upward when the mooring line is pulled. The anchor is to be secured with sufficiently high tensile resistance. Also, the water bottom has varying profiles. Fastening the anchor with sufficiently high tensile resistance is difficult in various water bottom environments.
Patent Literature 1: Japanese Unexamined Patent Application Publication No. 2002-211480
One or more aspects of the present invention are directed to firm installation of an anchor without relying on tensile resistance against an upward tensile force.
A mooring anchor according to an aspect of the present invention is a mooring anchor for securing a basal end of a mooring line underwater. The mooring anchor includes an anchor assembly to which the mooring line is to be fastened, and installable at a water bottom, and a guide to be secured at the water bottom at a position away from the anchor assembly. The guide includes a holder to receive and hold the mooring line in a movable manner. The anchor assembly includes a pile drivable into the water bottom and a tilted support extending obliquely downward toward the guide at the water bottom and to be embedded in the water bottom.
This structure includes the guide that guides the mooring line having the basal end fastened to the anchor assembly along the water bottom, and holds the mooring line near the water bottom in a movable manner. When the mooring line is pulled, the anchor assembly remains installed with the pile against a tensile force. The anchor assembly in this state is thus supported by the tilted support extending in the same direction as the mooring line in the water bottom.
The mooring anchor according to the above aspect of the present invention allows the tilted support to withstand and overcome a tensile force applied to the anchor assembly along the water bottom, thus enabling firm installation of the anchor assembly without relying on tensile resistance against an upward tensile force.
The mooring anchor 11 includes an anchor assembly 31 and a guide 51. The anchor assembly 31 is installed at a water bottom 14. The mooring line 13 is fastened to the anchor assembly 31. The guide 51 is secured at the water bottom 14 at a position away from the anchor assembly 31. The mooring line 13 is placed through the guide 51 and is held in a movable manner. The secured position of the guide 51 is away from the anchor assembly 31 toward the mooring position of the mooring target 12. The distance between the anchor assembly 31 and the guide 51 is adjusted in accordance with the installation environment to, for example, about a few to ten meters. The mooring line 13 connecting the anchor assembly 31 to the mooring target 12 through the guide 51 may be long.
More specifically, the anchor assembly 31 includes a bar anchoring part 34, which is sunk to the water bottom 14 and to which the mooring line 13 is fastened, in addition to the piles 32 integral with the anchoring part 34 and the tilted support 33 integral with the anchoring part 34.
The anchoring part 34 is formed from steel. The anchoring part 34 has a ground contact surface 35 in contact with the water bottom 14. The anchoring part 34 may be formed from H-beam steel. The anchoring part 34 formed from H-beam steel is installed to have two parallel flanges being the upper and lower surfaces when in use. The length of the anchoring part 34 is set as appropriate to, for example, about a few meters when the anchoring part 34 has one pile 32 on each of the two ends in the longitudinal direction.
The basal end 13a of the mooring line 13 is fastened to a middle portion of the anchoring part 34 in the longitudinal direction. In the illustrated example, the mooring line 13 has, at the basal end 13a, an annular portion 13b wound around and hooked on the anchoring part 34. The mooring line 13 may be fastened in any other manner. As shown in
Each pile 32 is a rod having a screw blade 32a at its tip. Each pile 32 is driven into the water bottom 14, and then the upper end is fastened to and integrated with a side surface of the anchoring part 34. The piles 32 are fastened to the side surface of the anchoring part 34 from which the mooring line 13 extends. As shown in
The tilted support 33 is a bar of steel with an appropriate length. The steel may be H-beam steel. The tilted support 33 formed from H-beam steel is installed to have two parallel flanges standing erect when in use.
The tilted support 33 formed from H-beam steel does not have a sufficiently large surface on its distal end to receive pressure. The tilted support 33 thus has, on its distal end, a pressure receiving plate 41 being flanged. The pressure receiving plate 41 is square and is appropriately sized. Although the pressure receiving plate 41 may have another shape and may be, for example, circular, the square pressure receiving plate 41 has corners at its periphery and can have a stable posture at the water bottom 14.
As described above, the tilted support 33 extends obliquely and is embedded in the water bottom 14. Thus, the pressure receiving plate 41 is tilted with respect to the longitudinal direction of the tilted support 33 depending on the angle at which the tilted support 33 is embedded.
More specifically, when the tilted support 33 is tilted at an angle of 15 to 30 degrees with respect to the horizontal direction, the pressure receiving plate 41 may be at an angle of 0 to 30 degrees with respect to the vertical direction. The tilted support 33 may be tilted at an angle of 20 to 25 degrees with respect to the horizontal direction, and the pressure receiving plate 41 may be at an angle of 10 to 15 degrees with respect to the vertical direction. Thus, the pressure receiving plate 41 is tilted at an angle of about 80 degrees, instead of 90 degrees, with respect to the tilted support 33.
The tilted support 33 is integrally coupled to the anchoring part 34 at a position adjacent to a portion of the anchoring part 34 to which the mooring line 13 is fastened with a metal coupler 43 shown in
The metal coupler 43 includes a fitting 44, an engagement member 45, and a connector 46. The fitting 44 is fitted with a rear end of the tilted support 33. The engagement member 45 is engaged with an edge of an upper flange on the H-beam steel anchoring part 34 opposite to the ground contact surface 35. The connector 46 connects the fitting 44 and the engagement member 45.
The fitting 44 includes an upper plate 44a covering an upper surface of the tilted support 33, a lower plate 44b covering a lower surface of the tilted support 33, and a connecting plate 44c connecting the upper plate 44a and the lower plate 44b. When fitted with the rear end of the tilted support 33, the fitting 44 protrudes outward from two side surfaces of the tilted support 33.
The engagement member 45 includes a staple-shaped connecting part 45a and tabs 45b. The connecting part 45a covers, from above, and extends across the tilted support 33. The tabs 45b are located on the lower ends of the connecting part 45a. Each tab 45b is bent at an obtuse angle at the corresponding lower end of the connecting part 45a toward the fitting 44.
The connector 46 includes two bolts 46a and nuts 46b screwed with the bolts 46a. The bolts 46a are held above the tabs 45b on the engagement member 45 and have their distal ends received in through-holes 47 in two ends of the connecting plate 44c in the fitting 44.
The guide 51 includes a pile member that is driven into the water bottom 14, similarly to the piles 32 described above. Thus, the guide 51 is a rod and has a screw blade 51a at its tip (refer to
The mooring anchor 11 with the above structure is installed in the manner described below.
As shown in
After the water bottom 14 is dug to embed the tilted support 33, the tilted support 33 is integrally coupled to the anchoring part 34 with the metal coupler 43. The tilted support 33 is then embedded.
The guide 51 is driven into the water bottom 14 on the extension of the mooring line 13 in the extending direction of the tilted support 33 in the anchor assembly 31. The holder 52 at the upper end of the guide 51 then receives the free end of the mooring line 13 fastened to the anchor assembly 31.
The water bottom 14 shown in
For a relatively soft cohesive soil layer 14c under the topsoil layer 14b at the water bottom 14, the foundation is consolidated as shown in
The hollow rectangular prism 61 is formed from metal and has a height greater than the thickness of the cohesive soil layer 14c. The hollow rectangular prism 61 is buried to extend perpendicularly from the foundation ground 14a to the topsoil layer 14b. The buried member, or the cylindrical hollow rectangular prism 61, is buried simply when driven, without the water bottom 14 being dug. The installation is thus easy. Also, the buried member, which is a hollow rectangular prism, is held in the water bottom 14 stably and firmly. The buried member may be of any shape other than a hollow rectangular prism.
The auxiliary plate 62 is formed from metal and extends from the cohesive soil layer 14c to the topsoil layer 14b. The auxiliary plate 62 extends perpendicularly from the cohesive soil layer 14c to the topsoil layer 14b along an outer surface of the hollow rectangular prism 61 adjacent to the anchor assembly 31. The hollow rectangular prism 61 is buried to extend from the foundation ground 14a to the topsoil layer 14b.
The riprap stones 63 are located around a corner defined by the surface of the cohesive soil layer 14c and the auxiliary plate 62 and adjacent to the anchor assembly 31, or specifically at the distal end of the tilted support 33.
In the mooring anchor 11 installed in the manner described above, the mooring line 13 extends from the anchor assembly 31 to the guide 51 along the water bottom 14 in a manner movable at the holder 52 in the guide 51 in the longitudinal direction. The mooring line 13 is movable in the horizontal direction as well at a position frontward from the holder 52.
When the mooring line 13 is pulled by the mooring target 12 that may move on the water surface with wind or may move due to the changing water level, the guide 51 changes a tensile force in the up-down (vertical) direction to be applied to the anchor assembly 31 through the mooring line 13 into a lateral tensile force, while retaining the mooring line 13 along the water bottom 14 in a movable manner.
The anchor assembly 31 remains installed with the piles 32 under a tensile force applied laterally through the mooring line 13. The tilted support 33 in the water bottom 14 prevents the piles 32 from being tilted or falling down.
Thus, the anchor assembly 31 can be installed firmly.
Also, the anchor assembly 31 includes the anchoring part 34 formed from H-beam steel, which is a heavy object, and the piles 32 fastened to the two ends of the anchoring part 34 in the longitudinal direction. The anchor assembly 31 can thus disperse applied gravity appropriately and have high tensile resistance.
The tilted support 33 includes the pressure receiving plate 41 on the distal end. A part of the tilted support 33 with the pressure receiving plate 41 is buried in the water bottom 14. This enables firmer installation.
The pressure receiving plate 41 is tilted with respect to the tilted support 33, and can stand in the manner described above when the tilted support 33 is tilted with respect to the horizontal direction. This structure appropriately disperses the tensile force received from the mooring line 13, enabling strong support.
Further, with the anchor assembly 31 and the guide 51 both driven into the water bottom 14 with piles, the workability is high. This enables relatively easy work underwater.
Another example of the present embodiment will now be described. The same components herein as those in the above structure are given the same reference numerals and will not be described in detail.
The tilted support 33 in the anchor assembly 31 is formed from H-beam steel as in the example described above. The tilted support 33 has a cutout 33b in a rear end of a web 33a of the steel H beam. The cutout 33b is large enough to receive the pile 32 in the rear end.
In the anchor assembly 31 described above, the pile 32 is driven into the water bottom 14, the tilted support 33 is tilted and driven into the water bottom 14, and the rear end of the tilted support 33 is fitted with the pile 32. This couples the tilted support 33 and the pile 32 together. The coupling may be performed by placing a bolt 65 through portions of the two flanges on the tilted support 33 that protrude outward from the pile 32.
When a mooring target 12 is small, the anchor may not have high tensile resistance and may have this simple structure.
This application is a continuation application of International Patent Application No. PCT/JP2018/010250 filed on Mar. 15, 2018, the entire content of which is incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
6457908 | Bergeron | Oct 2002 | B1 |
6685396 | Bergeron | Feb 2004 | B1 |
20110154636 | Smith | Jun 2011 | A1 |
20200130782 | Smith | Apr 2020 | A1 |
20200407022 | Kinjo | Dec 2020 | A1 |
Number | Date | Country |
---|---|---|
1011565 | Jun 1977 | CA |
2492460 | May 2002 | CN |
2736251 | Oct 2005 | CN |
1882472 | Dec 2006 | CN |
101886400 | Nov 2010 | CN |
103052561 | Apr 2013 | CN |
20462200 | Sep 2017 | CN |
58-126279 | Jul 1983 | JP |
S58-126279 | Jul 1983 | JP |
S60-108598 | Jul 1985 | JP |
S60-192018 | Sep 1985 | JP |
2002-211480 | Jul 2002 | JP |
2016-113123 | Jun 2016 | JP |
2016113123 | Jun 2016 | JP |
10-2015-0055727 | May 2015 | KR |
2005-108198 | Nov 2005 | WO |
2019176057 | Sep 2019 | WO |
WO-2019176057 | Sep 2019 | WO |
Entry |
---|
Office Action issued in Chinese Patent Application No. 201880090434.1 dated Nov. 2, 2021 with English Translation (12 pages). |
International Search Report issued in PCT/JP2018/010250 dated Apr. 17, 2018 with English Translation (5 pages). |
Office Action issued in Japanese Patent Application No. 2019-111667 dated Jul. 9, 2019 with English Translation (4 pages). |
Office Action issued in Taiwanese Patent Application No. 107122172 dated Oct. 1, 2021 (8 pages). |
Number | Date | Country | |
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20200407022 A1 | Dec 2020 | US |
Number | Date | Country | |
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Parent | PCT/JP2018/010250 | Mar 2018 | US |
Child | 17021610 | US |