JP7033187B1 - Culm anchor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an anchor capable of easily performing a dropping operation and a lifting operation from a ship. SOLUTION: An anchor 1 is located in a central portion 3 having through holes 3c and 3d penetrating vertically and below the central portion 3, and extends on both sides in the X-axis direction and has a claw 6 at the tip. Two arms 5 having, a weight 24 located below the two arms 5 and moving up and down between the lowest point PL and the highest point PH, and at least a part in through holes 3c and 3d. The shafts 21 and 22.23, which are arranged and whose lower ends are connected to the upper part of the weight 24, and the shafts 21 and 22 and 23 inside the central portion 3, rotate around the axis in the X-axis direction and are connected to the central portion. It includes two stocks 27, each protruding from an opening 3e formed on both sides of the third in the Y-axis direction. The two stocks 27 are folded with the weight 24 at the lowest point PL, and the two stocks 27 are unfolded with the weight 24 at the highest point PH. [Selection diagram] FIG. 5

Description

The present invention relates to an anchor with stock.

Conventionally, as an anchor used to keep a ship in a certain place, two arms having claws provided at the tip of the shank part and two arms in the middle of the shank part are orthogonal to each other. An anchor (stock anchor) with a protruding stock (culm) is used. The culm anchor has a high ability to anchor the ship because the stock or claws are thrust against the seabed when it is lowered to the seabed, but when it is pulled up and stored on the ship, the stock and the arm are crossed. There was a problem that it was difficult to store because it was protruding.

The culm anchor described in Patent Document 1 connects two stocks to the shank portion via a hinge, whereby the stock is rotated from a folded state in which the stock stands upright along the shank portion to an unfolded state orthogonal to the shank portion. It is made to move, and the tip of the chain connecting the anchor and the ship is bifurcated and connected to the middle part of the two stocks. The culm anchor of Patent Document 1 can be accommodated in a narrow space by being folded on board. When using the culm anchor of Patent Document 1, the two stocks are made by lowering the anchor from the ship into the sea in a folded state, pulling the culm anchor that has landed on the seabed, and applying a force to pull the anchor from the chain to the stock. It is rotated to the unfolded state.

Japanese Unexamined Patent Publication No. 62-15193

However, the culm anchor described in Patent Document 1 has a problem that the stock interferes with the hull and it takes time and effort to accommodate the anchor even when it is pulled up from the sea to the ship after anchoring. There was room for further improvement in order to facilitate the dropping work (anchoring) and the lifting work (anchoring).

Therefore, an object of the present invention is to provide an anchor anchor capable of easily performing a drop operation and a withdrawal operation from a ship.

The anchor of the present invention has a central portion having a through hole that penetrates vertically and two arms that are located below the central portion and extend on both sides in one direction and have claws at the tips. A weight that is located below the two arms and moves up and down between the lowest and highest points, and at least part of it is located in the through hole and the lower end is connected to the top of the weight. The shaft and the shaft are connected to the inside of the central portion, rotate around the axis in the one direction, and project from openings formed on both sides of the central portion in a direction orthogonal to the one direction. The two stocks are provided, the two stocks are folded with the weight at the lowest point, and the two stocks are unfolded with the weight at the highest point.

According to the present invention, the dropping work and the lifting work from the ship can be easily performed.

Front view of the culm anchor weight of one embodiment of the present invention in a lowered state. Side view of the state where the weight of the culm anchor according to the embodiment of the present invention is lowered. Front view of the culm anchor weight of the embodiment of the present invention in a raised state. Side view of the state where the weight of the culm anchor according to the embodiment of the present invention is raised. (A) Side sectional view of the culm anchor according to the embodiment of the present invention (a) Side sectional view of the anchor with the weight lowered (b) Side sectional view of the anchor with the weight raised. Configuration explanatory view of the stock opening / closing mechanism provided in the culm anchor according to the embodiment of the present invention. (A) (b) (c) Process explanatory view for installing the culm anchor according to the embodiment of the present invention on the seabed. (A) (b) (c) Schematic diagram of the process of lifting the culm anchor according to the embodiment of the present invention from the seabed.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The configuration and shape described below are examples for explanation, and can be changed as appropriate according to the specifications of the anchor. In the following, the corresponding elements are designated by the same reference numerals in all the drawings, and duplicate description will be omitted.

First, the configuration of the culm anchor 1 (stock anchor) will be described with reference to FIGS. 1 to 4. The culm anchor 1 includes an upper structure 2, a central portion 3, and a lower structure 4. The lower structure 4 includes two arms 5 extending in the left-right direction from the center in the up-down direction (Z-axis direction). Hereinafter, the direction in which the two arms 5 extend is referred to as the X-axis direction. Claws 6 are installed at the tips of the two arms 5, respectively. The claw 6 has a shape in which the culm anchor 1 is lowered to the seabed and anchored to the seabed. In this example, the tip end side of the arm 5 has a pointed substantially triangular plate shape. The shape of the claw 6 can be freely designed.

The upper center of the lower structure 4 is connected to the lower protrusion 3a of the central portion 3 by two first bolts 7 mounted from the right side and the left side (left and right in the X-axis direction), respectively. With this configuration, the lower structure 4 swings with respect to the central portion 3 with the X-axis direction as the rotation axis (arrow c in FIG. 4). That is, the two arms 5 are formed in the lower structure 4 which is swingably connected to the lower part (lower protruding portion 3a) of the central portion 3 about an axis in one direction (X-axis direction).

The upper structure 2 is configured to include two left and right side plates 8 and a horizontal plate 9 connecting the two side plates 8 at the upper part. A connecting portion 10 connected to the chain 11 is installed on the upper surface of the horizontal plate 9. The lower portions of the left and right side plates 8 of the upper structure 2 are connected to the upper protruding portion 3b of the central portion 3 by two second bolts 12 mounted from the right side and the left side (left and right in the X-axis direction), respectively. With this configuration, the superstructure 2 swings with respect to the central portion 3 with the X-axis direction as the rotation axis (arrow d in FIG. 4). In the upper structure 2, the space surrounded by the two side plates 8 and the horizontal plate 9 constitutes a relief space 2a that does not interfere with the upper shaft 21 that moves up and down.

In this way, the upper end (connecting portion 10) of the upper structure 2 is connected to the chain 11, and the lower end (lower part of the two side plates 8) is in one direction (upper protruding portion 3b) of the central portion 3. It is oscillatingly connected around the axis (in the X-axis direction). As a result, the superstructure 2 freely rotates with respect to the central portion 3, and the drop work (anchor) of dropping the culm anchor 1 from the ship to the sea and the lifting work (lifting work) of lifting the anchor 1 from the sea to the ship are performed. It can be done easily. Further, in the anchored state where the culm anchor 1 lands on the seabed and falls sideways, and the claw 6 and the stock 27 (pointed portion 28) are pushed to the seabed, the upper structure 2 rotates the shaking of the chain 11. By absorbing it, the anchored state can be maintained well (see FIG. 8 (a)).

A stock opening / closing mechanism 20 is arranged inside the upper structure 2, the central portion 3, and the lower structure 4. Here, the configuration of the stock opening / closing mechanism 20 will be described with reference to FIGS. 5 and 6. The stock opening / closing mechanism 20 includes an upper shaft 21, a central shaft 22, and a lower shaft 23 made of a hard rod-shaped material such as metal. A weight 24 is integrally connected to the lower end of the lower shaft 23. The weight 24 is made of a heavy and hard material such as a substantially spherical metal. The upper end of the lower shaft 23 is connected to the lower end of the central shaft 22 by the first pin 25 in the X-axis direction. With this configuration, the lower shaft 23 swings with respect to the central shaft 22 with the X-axis direction as the rotation axis.

Two shaft connecting portions 22a extending in the front side and the rear side in the direction orthogonal to the X-axis direction (Y-axis direction) in the horizontal plane are formed on the upper portion of the central shaft 22. One end of the stock 27 extending in the Y-axis direction is connected to each of the two shaft connecting portions 22a by the second pin 26 in the X-axis direction. With this configuration, the two stocks 27 rotate with respect to the central shaft 22 with the X-axis direction as the rotation axis. In the stock 27, a sharpened portion 28 is arranged at the tip opposite to one end connected to the shaft connecting portion 22a. The sharpened portion 28 has a shape in which the culm anchor 1 is lowered to the seabed and anchored to the seabed. In this example, it has the shape of a substantially quadrangular pyramid with a sharp tip. Instead of arranging the sharpened portion 28 at the tip of the stock 27, the shape of the tip of the stock 27 may be processed into a shape such as a quadrangular pyramid whose tip side is sharp.

The lower end of the upper shaft 21 is connected to the upper end of the central shaft 22 by a third pin 29 in the Y-axis direction. With this configuration, the upper shaft 21 swings with respect to the central shaft 22 with the Y-axis direction as the rotation axis.

In FIG. 5, a lower through hole 4a penetrating vertically in the center of the lower structure 4, a central lower through hole 3c penetrating vertically in the lower part of the central portion 3, and a central lower through hole 3c penetrating vertically in the upper part of the central portion 3 Central upper through holes 3d are formed. The central shaft 22 and the lower shaft 23 move up and down in the lower through hole 4a, the central shaft 22 and the lower shaft 23 move up and down in the central lower through hole 3c, and the upper shaft 21 and the central shaft 22 move up and down in the central upper through hole 3d. Arranged as possible.

A weight locking surface 4b having a curved surface corresponding to the shape of the upper surface of the weight 24 is formed on the lower surface of the center of the lower structure 4. When the weight 24 moves with respect to the lower structure 4 by a distance H from the position farthest from the lower structure 4 (the state of FIG. 5A), the upper surface of the weight 24 hits the weight locking surface 4b. It touches and stops (state of FIG. 5B). Hereinafter, the position where the weight 24 is farthest from the lower structure 4 is referred to as "lowest point PL", and the position where the weight 24 is in contact with the weight locking surface 4b is referred to as "highest point PH". When the weight 24 moves up and down between the lowest point PL and the highest point PH, the upper shaft 21, the central shaft 22, and the lower shaft 23 also move up and down together with the weight 24. As described above, a weight locking surface 4b with which the weight 24 at the uppermost point PH abuts is formed on the lower surface of the lower structure 4.

In FIG. 5, openings 3e on which the stock 27 protrudes are formed on the front and rear side surfaces of the central portion 3 in the Y-axis direction. A storage space 30 in which the stock 27 is stored is formed inside the central portion 3. The storage space 30 is oblique toward the horizontal lower contact surface 30a with which the lower surface of the shaft connecting portion 22a abuts and the opening 3e with which the lower surface 27a of the stock 27 abuts while the weight 24 is located at the lowest point PL. An oblique contact surface 30b that is inclined toward the surface is formed. With the weight 24 located at the lowest point PL, the stock 27 is folded into a stored state with the smallest amount of protrusion from the central portion 3 (state of FIG. 5A).

The storage space 30 is horizontal with the middle contact surface 30c to which the lower surface 27a of the stock 27 opened horizontally in the Y-axis direction abuts with the weight located at the highest point PH, and the upper surface of the shaft connecting portion 22a to abut. The upper contact surface 30d is formed. In this example, the central contact surface 30c coincides with the lower side of the opening 3e. With the weight 24 located at the highest point PH, the stock 27 is in an expanded state horizontally open in the Y-axis direction (state of FIG. 5B). The weight 24 abuts on the weight locking surface 4b, the lower surface 27a of the stock 27 abuts on the middle abutting surface 30c, and the upper surface of the shaft connecting portion 22a abuts on the upper abutting surface 30d, whereby the stock 27 is in an expanded state. Is well maintained.

In FIG. 5A, in the stored state where the weight 24 is located at the lowest point PL, the central shaft 22 is located at a position straddling the central portion 3 and the lower structure 4, so that the lower structure 4 is relative to the central portion 3. Cannot swing. In FIG. 5B, in the deployed state where the weight 24 is located at the highest point PH, the position of the first pin 25 connecting the central shaft 22 and the lower shaft 23 is the position connecting the central portion 3 and the lower structure 4. It coincides with the position of 1 bolt 7. Therefore, the lower shaft 23 is integrated with the lower structure 4, the central shaft 22 is integrated with the central portion 3, and can swing with the X-axis direction as the rotation axis (arrow c in FIG. 4).

As described above, the shaft (center shaft 22, lower shaft 23) is a connection point (first) that can swing integrally with the central portion 3 and the lower structure 4 in the deployed state where the weight 24 is at the uppermost point PH. It has a pin 25). By freely rotating the stock 27 (pointed portion 28) of the central portion 3 and the arm 5 and the claw 6 of the lower structure 4 in the deployed state, the uneven shape of the seabed when the culm anchor 1 anchors to the seabed. The claw 6 and the stock 27 (pointed portion 28) can be appropriately thrust to the seabed according to the situation (see FIG. 7 (c)).

Further, the upper shaft 21 and the central shaft 22 are connected by the third pin 29 so as to be swingable with each other with the Y-axis direction as the rotation axis, so that the X-axis is formed with respect to the vertical movement of the central shaft 22 along the Z-axis direction. Some margin (play) is added in the direction and the Y-axis direction. As a result, the two stocks 27 can be smoothly rotated and stored according to the vertical movement of the central shaft 22.

As described above, the anchor 1 is located in the central portion 3 having a through hole (central lower through hole 3c, central upper through hole 3d) penetrating up and down at the center and below the central portion 3, and is one of the ones. It is located below the two arms 5 and the two arms 5 that extend in both directions (left and right) in the direction (X-axis direction) and have claws 6 at the tips, and is located between the lowest point PL and the highest point PH. A weight 24 that moves up and down, a shaft (upper shaft 21, center shaft 22, lower shaft 23) whose lower end is connected to the upper part of the weight 24 and at least a part thereof is arranged in a through hole, and a central portion 3. From the openings 3e formed on both sides in the direction (Y-axis direction) orthogonal to one direction of the central portion 3, which is internally connected to the shaft via the shaft connecting portion 22a and rotates around an axis in one direction. It has two stocks 27, each of which protrudes.

Then, the two stocks 27 are folded while the weight 24 is at the lowest point PL (FIG. 5A), and the two stocks 27 are unfolded while the weight 24 is at the highest point PH (FIG. 5). (B)). That is, as shown in FIG. 4, the weight 24 rises relatively with respect to the two arms 5 (lower structure 4) from the state where the weight 24 is at the lowest point PL indicated by the two-dot chain line (arrow a), and is a solid line. While reaching the highest point PH indicated by (arrow b), the two stocks 27 are folded from the stored state indicated by the two-dot chain line and stored in the central portion 3 (arrow b) and open horizontally as indicated by the solid line. Expand so that it is in the expanded state.

In FIG. 3, in the deployed state where the weight 24 is at the highest point PH, the lower end of the weight 24 is located below the lowermost surface of the two arms 5 (lower structure 4) by a distance L. That is, with the weight 24 at the highest point PH, at least a part of the weight 24 protrudes below the two arms 5. As a result, even if the culm anchor 1 that has landed on the seabed and is in the deployed state is laid down toward the seabed to anchor, the deployed state can be maintained well (see FIG. 7 (c)). ).

Next, with reference to FIG. 7, the process of dropping the culm anchor 1 into the sea from the ship (anchor) will be described. Here, the process until the anchor 1 descending in the sea becomes an anchor state will be described. In FIG. 7A, the culm anchor 1 connected to the chain 11 from the ship and dropped into the sea has two stocks because the weight 24 is pulled downward by gravity and is located at the lowest point PL. 27 is housed in the central portion 3 and descends toward the seabed B (arrow e1). Even when the culm anchor 1 is dropped from the ship, since the two stocks 27 are in the housed state, the dropping operation can be easily performed without the stocks 27 interfering with the hull.

In FIG. 7B, when the weight 24 has landed on the seabed B and then the chain 11 is further lowered, the upper structure 2, the central portion 3, and the lower structure 4 are integrally lowered (arrow e2). As a result, the weight 24 rises relatively to the highest point PH with respect to the lower structure 4 (arrow f), and the two stocks 27 are in a horizontally expanded state (arrow g).

In FIG. 7 (c), when the chain 11 is further lowered after the unfolded state (arrow e3), the anchor 1 is laid on its side toward the seabed B, and the claw 6 and the stock 27 (pointed portion 28) are on the seabed. It will be in a state of anchoring. In the process, the central portion 3 rotates relative to the lower structure 4 (arrow h), and the upper structure 2 rotates relative to the central portion 3 (arrow i). The claw 6 and the stock 27 can be appropriately thrust to the seabed according to the uneven shape of the seabed B.

Next, with reference to FIG. 8, a process of lifting work (lifting anchor) for lifting the anchor 1 from the sea to the ship will be described. Here, the process of lifting the anchor 1 (FIG. 8A) anchored on the seabed B from the seabed B will be described. In FIG. 8 (b), when the chain 11 connected to the culm anchor 1 is pulled upward toward the ship (arrow j1), the culm anchor 1 lying on the seabed B remains in the deployed state and is upper. Stand up so that the structure 2 is on top.

In FIG. 8 (c), when the chain 11 is further pulled upward (arrow j2), the weight 24 that has landed on the seabed B separates from the seabed B. As a result, the weight 24 is pulled downward by gravity and relatively descends to the lowest point PL with respect to the lower structure 4 (arrow k), and the two stocks 27 are housed in the central portion 3 (arrow). m). After that, the culm anchor 1 is pulled up to the ship in the housed state.

Since the two stocks 27 are still in the house while the anchor 1 is lifted from the surface of the water and collected on the ship, the stock 27 or the sharpened portion 28 may interfere with the hull and be caught or damaged. The lifting work can be easily performed without any problem. Further, when the hose pipe is arranged between the side surface of the ship and the ship (deck), the anchor 1 in the housed state can house the superstructure 2 and the central portion 3 in the hose pipe, and further. It does not damage the inner wall of the hose pipe.

As described above, the culm anchor 1 of the present embodiment is dropped into the sea from the ship in a housed state in which two stocks 27 are housed in the central portion 3, and is withdrawn from the sea. Therefore, the dropping work and the lifting work can be easily performed without the two stocks 27 interfering with the hull or the like.

Provide an anchor that can easily perform dropping work and lifting work from the ship.

1 culm anchor 2 superstructure 3 central part 3c central lower part through hole (through hole)
3d Central upper through hole (through hole)
3e Aperture 4 Substructure 4b Weight locking surface 5 Arm 6 Claw 11 Chain 21 Upper shaft (shaft)
22 Central shaft (shaft)
23 Lower shaft (shaft)
24 Weight 25 1st pin (connection point)
27 Stock PH highest point PL lowest point

Claims (5)

The central part, which has a through hole that penetrates up and down,
Two arms located below the central part, extending on both sides in one direction and having claws at the tips,
A weight that is located below the two arms and moves up and down between the lowest and highest points.
With a shaft that is at least partly located in the through hole and whose lower end is connected to the top of the weight.
Two pieces that are connected to the shaft inside the central portion, rotate about an axis in the one direction, and project from openings formed on both sides of the central portion in a direction orthogonal to the one direction. With stock,
An anchor in which the two stocks are folded with the weight at the lowest point and the two stocks are unfolded with the weight at the highest point. The two arms are formed in a lower structure that is swingably connected to the lower part of the central portion about the axis in one direction.
The anchor according to claim 1, wherein the shaft has a connection point that can swing together with the central portion and the lower structure in a state where the weight is at the uppermost point. The culm anchor according to claim 2, wherein a weight locking surface with which the weight at the uppermost point abuts is formed on the lower surface of the lower structure. The anchor according to any one of claims 1 to 3, wherein at least a part of the weight protrudes downward from the two arms while the weight is at the uppermost point. The anchor according to any one of claims 1 to 4, further comprising a superstructure having an upper end connected to a chain and a lower end swingably connected to the upper part of the central portion about the axis in one direction. Anchor.

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