JP2008049806A - Double-claw anchor for boat - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an anchor capable of easily performing the recovery of the anchor even if the anchor is hooked on a reef, returning a shank and a claw to an original state when the anchor is pulled up from the sea bottom, and further enhancing safety by reducing work that a person performs at a bow leaning his/her body forward as much as possible. <P>SOLUTION: A shank body 2 and one end of a shackle 24 are pivotably connected, and the other end of the shackle 24 and a connection member 15 of a claw body 11 are pivotably connected. A coil spring 10 penetrates the shank body 2, a nut 7 is screwed into with a screw of the shank body 2, and the tip of the coil spring 10 resiliently biases the end surface of the connection member 15. The claw 14 is hooked on the reef and an anchor body 1 is pulled up, and when a predetermined force or larger is applied to the coil spring 10, the coil spring 10 is bent and the claw 14 is easily removed from the reef. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a two-claw anchor for boats having a substantially arc-shaped claw on the left and right, called a Tangjin anchor.

  Conventionally, the two-claw anchor for boats that has been used in many boats and fishing boats is a universal type that has relatively no choice of seabed quality. However, due to its structure, when used in a rocky area, anchors (reeds) are often rooted and cannot be recovered, the sea environment is not good, and the safety of ships without anchors Will also have a major impact.

  On the other hand, anchors are required to have a particularly high level of holding power so that they do not come off or run while they are anchored or working. As described above, the present situation is that the holding ability is highly demanded while the anchor recovery is also demanded stably.

  For example, Patent Documents 1 to 3 listed below can be collected even when anchors are rooted in a rocky area.

JP 54-126389 A JP-A-1-182189 Japanese Patent Laid-Open No. 9-240576

The anchors described in these Patent Documents 1 to 3 give spring force to the claws, and even if the anchor claws are rooted on the seabed reef, by pulling the anchors as they are, the claws are inverted. The anchor can be collected.
However, such an anchor requires an operation of returning the claws again after being pulled up, and the operation while taking the body out at the tip of the bow is difficult and difficult.

  Moreover, even when the anchor is rooted on the reef, other examples that enable the recovery of the anchor include, for example, Patent Documents 4 to 6 shown below.

Japanese Unexamined Patent Publication No. 63-68484 Japanese Unexamined Patent Publication No. 1-190597 Japanese Patent Laid-Open No. 3-58953

In the techniques disclosed in these Patent Documents 4 to 6, a member that can be detached is connected to an end portion of an anchor shank, a rope is connected to the member, and a base portion side of the member and an anchor claw is connected. Also connected to the rope.
Normally, the rope is pulled up, but when rooted in the rock at the bottom of the sea, the anchor is recovered from the reef by separating the member from the shank and lifting the rope from the base of the anchor claw. It is something that can be done.

  However, even in the cases of Patent Documents 4 to 6, after the anchor is lifted, it is necessary to connect the member to the anchor shank, and this work is performed at the tip of the bow as in the case described above. The work while going out is difficult work as well as dangerous work.

The present invention is provided in view of the above-described problems, and provides a two-claw anchor for boats having at least the following objects.
(1) The anchor can be easily collected even when the anchor is rooted in the reef.
(2) When the anchor is lifted from the seabed, the shank and claws are restored to their original state.
(3) To provide an anchor with improved safety by minimizing the work to be carried out at the bow.

Therefore, in the two-claw anchor for a boat according to claim 1 of the present invention, a rod-shaped shank body 2 having an anchor link 3 to which a chain or a rope is connected on one end side and a screw portion 6 on the other end side. When,
A substantially W-shaped nail body 11 provided with nails 14 on the left and right,
A connecting portion that has a stock holding portion 21 that holds the stock 22 on the distal end side, and is fixed to the claw body 11 with a nut 23 through a center hole 12 that is drilled in the center portion of the claw body 11 on the base side. Member 15;
A connecting tool 24 in which the other end and one end side of the shank body 2 are swingably connected, and a base side and the other end side of the connecting member 15 are swingably connected;
A coil spring 10 that is inserted from one end of the shank body 2 and is attached to the shank body 2 so as to cover the connector 24;
The anchor body 1 is composed of a nut 7 that is screwed into the threaded portion 6 of the shank body 2 and elastically biases the coil spring 10 toward the claw body 11 side.

  The two-claw anchor for a boat according to claim 2 is characterized in that a coil spring 10 having a spring force corresponding to the magnitude of the holding force is detachably attached to the shank body 2.

  In the two-claw anchor for boats according to claim 3, the shank body 2 and the connecting member 15 are connected in a swingable manner by a shaft rod such as a bolt 62 instead of the connecting tool 24. Yes.

In the two-claw anchor for a boat according to claim 4, a cylindrical shank body 2 provided with an anchor link 3 to which a chain and a rope are connected at one end side and provided with a screw portion 30 on the inner peripheral surface at the other end side. When,
A cylindrical claw coupling portion 31 having one end side inserted into the shank body 2 and screwed to the screw portion 30;
A screw portion 35 is provided on one end side and disposed in the shank body 2, and the other end side is a spring fixing rod 34 located in the claw coupling portion 31.
A substantially W-shaped nail body 11 provided with nails 14 on the left and right,
A connecting portion that has a stock holding portion 21 that holds the stock 22 on the distal end side, and is fixed to the claw body 11 with a nut 23 through a center hole 12 that is drilled in the center portion of the claw body 11 on the base side. Member 15;
A connecting tool 24 in which the other end and one end of the spring fixing rod 34 are swingably connected, and the base side and the other end of the connecting member 15 are swingably connected;
A coil spring 40 disposed on the outer peripheral surface side of the spring fixing rod 34;
The end portion of the claw connecting portion 31 is elastically urged by the tip of the coil spring 40 and the other end surface of the claw connecting portion 31 is connected to the nut 23. The anchor main body 1 is composed of a nut 41 biased to the end face.

  The two-claw anchor for a boat according to claim 5 is characterized in that the nut 41 is used for adjusting the spring pressure of the coil spring 40.

  The two-claw anchor for a boat according to claim 6 is characterized in that the connecting member 15 and the claw connecting portion 31 are connected by a pin 50 that is cut when a predetermined force or more is applied.

  The two-claw anchor for a boat according to claim 7 is characterized in that the strength of the pin 50 is determined by the strength of the material of the pin 50.

  In the two-claw anchor for a boat according to claim 8, the spring fixing rod 34 and the connecting member 15 are slidably connected by a shaft rod such as a bolt 72 instead of the connecting member 24. It is said.

According to the two-claw anchor for a boat according to claim 1 of the present invention, when the claw 14 of the anchor main body 1 is rooted on the reef of the seabed, if the anchor main body 1 is pulled up as it is with the rope, the coil spring 10 When a force greater than the urging force is applied, the coil spring 10 itself bends and the claws 14 come off the reef, and the anchor body 1 can be easily recovered.
In the middle of pulling up the anchor body 1, the coil spring 10 is returned to the axial direction by the spring force of the coil spring 10, and the claw body 11 is automatically returned to the original state with respect to the shank body 2. Therefore, there is no need for the work of lifting the anchor main body 1 after the anchor main body 1 as in the prior art and returning the claws to the original state, and the safety can be further improved.

  According to the two-claw anchor for a boat according to claim 2, since the coil spring 10 having a spring force corresponding to the magnitude of the holding force is detachable from the shank body 2, the coil springs 10 having different spring forces are preliminarily attached. A plurality of coil springs 10 having a desired holding force can be appropriately attached to the anchor main body 1 according to the size of the ship.

  According to the two-claw anchor for a boat according to claim 3, since the shank body 2 and the connecting member 15 are swingably connected by a shaft rod such as a bolt 62 instead of the connecting tool 24. When the coil spring 10 is bent, the claw body 11 can be detached from the reef or the nail body 11 can be returned to the original state with respect to the shank body 2 without interfering with the bending and return operations of the coil spring 10. it can.

According to the two-claw anchor for a boat according to claim 4, when the anchor body 1 rooted on the reef 43 is pulled up, the coil spring 40 is moved by the spring holding portion 42 of the claw connecting portion 31 in the direction of the arrow B in the axial direction. A force is applied in the direction, whereby the coil spring 40 is contracted in the direction of arrow B (see FIG. 12).
This means that the claw connecting portion 31 and the shank body 2 move upward with respect to the claw body 11, the connecting member 15, and the spring fixing rod 34, and the claw connecting portion 31 and the shank body 2 are pulled up by a predetermined amount or more. Then, the connecting member 15 and the shackle 24 that are located in the claw connecting portion 31 and are connected to the claw main body 11 are exposed, and the claw main body 11 is free to swing with respect to the claw connecting portion 31. Become.
Therefore, the claw body 11 that can freely swing with respect to the tip of the spring fixing rod 34 is detached from the reef 43, and the anchor body 1 can be pulled up as it is, and the anchor body 1 is easily recovered. be able to.

Further, in the middle of pulling up the anchor main body 1 detached from the reef 43, a force is applied to urge the claw coupling portion 31 and the shackle 24 toward the claw main body 11 with respect to the spring fixing rod 34 by the spring pressure of the coil spring 40. While the shackle 24 and a part of the connecting member 15 are housed in the claw connecting portion 31, the tip surface of the claw connecting portion 31 comes into contact with the end surface of the nut 23 of the claw body 11, and the claw body 11 is connected to the claw. The position automatically returns to the original position with respect to the portion 31.
As a result, the anchor main body 1 is rooted on the reef 43, the claw main body 11 is freely swingable with respect to the claw coupling portion 31 and the shank body 2, and the claw main body 11 is detached from the reef 43, and the anchor main body is removed. Even if 1 is pulled up, the claw body 11 automatically returns to the original position with respect to the claw connecting portion 31, so that it is not necessary to perform any work for returning the anchor body 1 to its original state after lifting the anchor body 1. For this reason, the work of getting on the bow is unnecessary, and the safety can be further improved.

  According to the two-claw anchor for a boat according to claim 5, since the nut 41 is used for adjusting the spring pressure of the coil spring 40, it depends on the magnitude of the holding force or the size of the ship. In the case where the holding force is adjusted, the position of the nut 41 for adjusting the spring pressure of the coil spring 40 can be adjusted easily.

According to the two-claw anchor for a boat according to claim 6, the connecting member 15 and the claw connecting portion 31 are connected by the pin 50 that is cut when a predetermined force or more is applied. When the anchor body 1 is pulled up by being rooted in the reef 43, a force is applied in a direction orthogonal to the axial direction of the pin 50, and the pin 50 is cut when the force exceeds a predetermined value. When the pin 50 is cut, a force is applied to the coil spring 40 in the direction indicated by the arrow B in the axial direction by the spring holding portion 42 of the claw coupling portion 31, whereby the coil spring 40 is contracted in the direction indicated by the arrow B (FIG. 21).
This means that the claw connecting portion 31 and the shank body 2 move upward with respect to the claw body 11, the connecting member 15, and the spring fixing rod 34, and the claw connecting portion 31 and the shank body 2 are pulled up by a predetermined amount or more. Then, the connecting member 15 and the shackle 24 that are located in the claw connecting portion 31 and are connected to the claw main body 11 are exposed, and the claw main body 11 is free to swing with respect to the claw connecting portion 31. Become.

Therefore, the claw body 11 that is freely rotatable with respect to the tip of the spring fixing rod 34 is detached from the reef 43, the anchor body 1 can be pulled up as it is, and the anchor body 1 is easily recovered. be able to.
Further, in the middle of pulling up the anchor main body 1 detached from the reef 43, a force is applied to urge the claw coupling portion 31 and the shackle 24 toward the claw main body 11 with respect to the spring fixing rod 34 by the spring pressure of the coil spring 40. While the shackle 24 and a part of the connecting member 15 are housed in the claw connecting portion 31, the tip surface of the claw connecting portion 31 comes into contact with the end surface of the nut 23 of the claw body 11, and the claw body 11 is connected to the claw. The position automatically returns to the original position with respect to the portion 31.

  As a result, the anchor main body 1 is rooted on the reef 43, the claw main body 11 is freely rotatable with respect to the claw coupling portion 31 and the shank body 2, and the claw main body 11 is detached from the reef 43, and the anchor main body is removed. Even if 1 is pulled up, the claw body 11 automatically returns to the original position with respect to the claw connecting portion 31, so that it is not necessary to perform any work for returning the anchor body 1 to its original state after lifting the anchor body 1. For this reason, the work of getting on the bow is unnecessary, and the safety can be further improved.

When the seabed is sandy or mud and the pin 50 is not provided as in the first and second embodiments, if the spring force of the coil springs 10 and 40 is weak, the claw 14 of the anchor body 1 is Even if the nail body 11 is bent on the seabed, the nail body 11 may be bent with respect to the shank body 2, and the nail 14 may not be hooked on the seabed.
However, since the pin 50 is provided, the claw body 11 maintains the posture of the anchor body 1 itself without bending with respect to the shank body 2 side as long as the force for cutting the pin 50 is not applied. The claw 14 of the anchor body 1 can be reliably hooked on the seabed.

  According to the two-claw anchor for a boat according to claim 7, since the strength of the pin 50 is applied by the strength of the material of the pin 50, when changing the holding force, according to the holding force. The holding force can be easily changed as appropriate simply by using the pin 50 made of a different material.

  According to the two-claw anchor for a boat according to claim 8, since the spring fixing rod 34 and the connecting member 15 are slidably connected by a shaft rod such as a bolt 72 instead of the connector 24. When the coil spring 40 bends, the claw body 11 can be detached from the reef or the nail body 11 can be returned to the original state with respect to the shank body 2 without interfering with the bending or returning operation of the coil spring 40. Can do.

(First embodiment)
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings (FIGS. 1 to 5). 1 is a perspective view of the anchor body 1, FIG. 2 (a) is a plan view of the anchor body 1, FIG. 2 (b) is a front view, and FIG. 3 is an exploded perspective view of the anchor body 1. Yes.

1 to 3, a shank body 2 as a central axis rod of the anchor body 1 is formed in a columnar shape or a cylindrical shape (pipe shape), and one end of the shank body 2 is connected to a chain or a rope. An anchor link 3 is formed. A connecting piece 4 is formed at the other end of the shank body 2, and a connecting hole 5 is drilled in the connecting piece 4.
Further, a screw portion 6 is screwed on the outer peripheral surface of the other end side of the shank body 2, and a nut 7 for holding the coil spring 10 is attached to the screw portion 6 so as to be freely screwed.

The claw body 11 having a substantially W shape has a center portion 13 that has a central center hole 12 drilled therein, and a pair of substantially arc-shaped claws 14 that are integrally extended from both sides of the center portion 13. It consists of and.
The connecting member 15 for connecting the claw body 11 to the shank body 2 side is formed in a cylindrical or columnar shape, and the outer diameter of the connecting member 15 is set smaller than the inner diameter of the center hole 12 of the claw body 11. Has been.

A connecting piece 17 having a hole 16 is integrally formed at one end of the connecting member 15, and a screw portion 20 is formed at the other end of the connecting member 15. In addition, a cylindrical stock holding portion 21 having an axial direction in a direction orthogonal to the axial direction of the connecting member 15 is integrally formed at the other end of the connecting member 15, and the stock holding portion 21 has a cylindrical shape. When the stock 22 is press-fitted, the stock 22 is firmly held by the stock holding portion 21.
The stock 22 is a rod that prevents the claw 14 of the anchor body 1 from rolling over on the seabed, and the material is made of wood, metal, plastic, or the like.

Next, the connection method of the nail | claw main body 11 and the shank body 2 is demonstrated. The connecting member 15 is fixed to the claw body 11 by inserting the connecting member 15 into the center hole 12 of the claw body 11 and screwing the nut 23 into the screw portion 20 of the connecting member 15.
Next, one end side of the shackle 24 is inserted into the hole 5 of the shank body 2, the other end side of the shackle 24 is inserted into the hole 5 of the connecting member 15, and the adjusting member 25 is screwed, so that the shackle 24 The ends are connected to each other, whereby the shackle body 11 and the shank body 2 are connected to each other so as to be swingable by the shackle 24.

After the claw body 11 and the shank body 2 are connected in a chain shape by the shackle 24, the coil spring 10 is inserted from the shank body 2, and the nut 7 is inserted into the shank body 2 and screwed into the screw portion 6. The coil spring 10 is compressed.
Due to the spring force (restoring force) of the coil spring 10, the tip of the coil spring 10 elastically biases the claw body 11 toward the tip, and the claw body 11 moves against the shank body 2 as shown in FIG. It is held in an orthogonal state.

  When the claws 14 of the anchor main body 1 are rooted on the seabed reef, normally, the spring force of the coil spring 10 becomes a holding force, so that the detachment and the anchorage do not occur. When the anchor body 1 is pulled up, even if the anchor body 1 is rooted, if the rope is pulled up as it is, a force greater than the urging force of the coil spring 10 is applied as shown in FIGS. Then, the coil spring 10 itself is bent, and the claw 14 is detached from the reef, so that the anchor body 1 can be easily recovered.

While the anchor body 1 is being pulled up, the coil spring 10 is returned to the axial direction by the spring force of the coil spring 10, and the claw body 11 is automatically returned to the original state as shown in FIG. Will return to.
Therefore, there is no need for the work of lifting the anchor main body 1 after the anchor main body 1 as in the prior art and returning the claws to the original state, and the safety can be further improved.

  In the present embodiment, the magnitude of the holding force of the anchor body 1 is determined by appropriately changing the wire diameter of the coil spring 10 itself. The coil spring 10 can be easily removed and attached by removing or attaching the nut 7. Thus, since the coil spring 10 is configured to be detachably attached to the shank body 2, a plurality of coil springs 10 having different spring forces are prepared in advance, and a desired holding force can be obtained according to the size of the ship. The coil spring 10 can be appropriately attached to the anchor body 1.

(Second Embodiment)
Next, a second embodiment will be described with reference to FIGS. In addition, the same number is attached | subjected and demonstrated to the element which exhibits the same function as 1st Embodiment. 6 is a perspective view of the anchor body 1, FIG. 7 is a plan view of the anchor body 1, FIG. 8 is an exploded perspective view of the anchor body 1, and FIG. 9 is a sectional view of the anchor body 1. ing.

As shown in FIGS. 8 and 9, the shank body 2 uses a pipe-like object in the present embodiment, and a screw portion 30 is threaded on the inner peripheral surface of the shank body 2 on the side opposite to the anchor link 3. Has been. The claw coupling portion 31 attached to the screw portion 30 of the shank body 2 is formed in a cylindrical shape, and both ends are open.
On the outer peripheral surface of the small-diameter portion 32 of the connecting member 15, a screw portion 33 that is screwed with the screw portion 30 of the shank body 2 is threaded.

The spring fixing rod 34 disposed in the shank body 2 is formed in a columnar shape or a cylindrical shape, and a screw portion 35 is screwed on the outer peripheral surface of one end side of the spring fixing rod 34. A connecting piece 37 having a hole 36 connected to the shackle 24 in a swingable manner is integrally formed on the other end surface side of the spring fixing rod 34.
A coil spring 40 is mounted on the outer periphery of the spring fixing rod 34, and the spring pressure of the coil spring 40 is applied by a nut 41 that is screwed into the threaded portion 35 of the shank body 2 so as to be able to advance. That is, the nut 41 is used for adjusting the spring pressure of the coil spring 40.

The claw body 11 and the connecting member 15 are connected and held in the same manner as in the previous embodiment, and the connecting member 15 and the spring fixing bar 34 are both connected by a shackle 24 as shown in FIG. It is linked in a chain and swingable.
FIG. 9 shows a state where the nut 41 is positioned at the end of the spring fixing rod 34, and FIG. 10 shows a state where the nut 41 is screwed and the spring pressure of the spring fixing rod 34 is increased.

The connecting member 15 on the claw body 11 side and the spring fixing rod 34 are connected in a chain shape with a shackle 24 to form a series, and in this state, the connecting member 15 is connected to the claw body 11 side via the spring fixing rod 34. To put on. At this time, the front end surface of the claw coupling portion 31 is positioned up to the end surface of the nut 23.
Next, the coil spring 40 is attached to the spring fixing rod 34, and the nut 41 is screwed into the screw portion 35 of the spring fixing rod 34 to be screwed to a position where a desired spring pressure is obtained. In this state, the shank body 2 is covered with the spring fixing rod 34 so that the screw portion 30 of the shank body 2 and the screw portion 33 of the spring fixing rod 34 are screwed together, and the tip surface of the shank body 2 is the claw coupling portion. Screwing is performed until it comes into contact with the end face of the step portion 31.

FIG. 11 shows an enlarged cross-sectional view in such a case, and the distal end surface of the coil spring 40 is brought into pressure contact with the spring holding portion 42 which is the distal end surface of the small diameter portion 32 of the claw coupling portion 31 by the spring pressure of the coil spring 40. 40 is held by a spring holding portion 42. As shown in FIG. 10, the coil spring 40 is compressed by a nut 41, and the claw coupling portion 31 that is biased by this spring force biases the claw body 11.
As a result, the shackle 24 and a part of the connecting member 15 are located in the claw connecting portion 31, and the claw body 11 is in a state orthogonal to the spring fixing rod 34 and the shank body 2.

FIG. 12 shows a state in which the anchor main body 1 is rooted on the reef 43, and the rope main body is going to be pulled up in the direction indicated by the arrow a in the figure through the chain 44 connected to the anchor link 3 of the anchor main body 1. When the anchor main body 1 is pulled up, a force is applied to the coil spring 40 in the direction of the arrow B in the axial direction by the spring holding portion 42 of the claw coupling portion 31, whereby the coil spring 40 is contracted in the direction of the arrow B.
This means that the claw connecting portion 31 and the shank body 2 move upward with respect to the claw body 11, the connecting member 15, and the spring fixing rod 34, and the claw connecting portion 31 and the shank body 2 are pulled up by a predetermined amount or more. Then, as shown in FIG. 13, the connecting member 15 and the shackle 24 that are located in the claw connecting portion 31 and are connected to the claw main body 11 are exposed, and the claw main body 11 is free to the claw connecting portion 31. Becomes swingable. In this case, the nail body 11 side and the shank body 2 side are free from each other, and are in a swingable relationship with each other.

  Therefore, the claw body 11 that can freely swing with respect to the tip of the spring fixing rod 34 is detached from the reef 43, and the anchor body 1 can be pulled up as it is. FIG. 14 shows a case where the anchor body 1 is pulled up by moving the position of the ship, and the connecting member 15 of the claw body 11 is free with respect to the spring fixing rod 34 by pulling up with a force exceeding a predetermined value. Thus, the claw 14 of the claw body 11 is detached from the reef 43, and the anchor body 1 can be easily recovered.

  Further, in the middle of pulling up the anchor main body 1 detached from the reef 43, the claw coupling portion 31 and the shackle 24 are moved toward the claw main body 11 with respect to the spring fixing rod 34 by the spring pressure of the coil spring 40 as shown in FIG. Since the energizing force works, while the shackle 24 and a part of the connecting member 15 are stored in the claw connecting portion 31, the front end surface of the claw connecting portion 31 comes into contact with the end surface of the nut 23 of the claw body 11. The nail body 11 automatically returns to the original position with respect to the nail connecting portion 31.

  As a result, the anchor main body 1 is rooted on the reef 43, the claw main body 11 is freely swingable with respect to the claw coupling portion 31 and the shank body 2, and the claw main body 11 is detached from the reef 43, and the anchor main body is removed. Even if 1 is pulled up, the claw body 11 automatically returns to the original position with respect to the claw connecting portion 31, so that it is not necessary to perform any work for returning the anchor body 1 to its original state after lifting the anchor body 1. For this reason, the work of getting on the bow is unnecessary, and the safety can be further improved.

  In addition, when adjusting the holding force according to the magnitude of the holding force or according to the size of the ship, the position of the nut 41 for adjusting the spring pressure of the coil spring 40 can be adjusted easily. It can be done.

  Further, conventionally, when the anchor main body 1 is rooted on the reef and the anchor main body 1 cannot be detached from the reef, the rope main body is not cut and the anchor main body 1 is not pulled up, but left on the seabed. However, in the first and second embodiments of the present invention, since the anchor body 1 can be easily recovered, the anchor body 1 is not abandoned on the seabed. Therefore, there is no harm to the natural environment, and there is no need to purchase and re-install the anchor main body 1 again. As a result, the anchor main body 1 can be provided at low cost.

(Third embodiment)
Next, a third embodiment will be described with reference to FIGS. The structure of the anchor body 1 of the present embodiment is almost the same as that of the second embodiment, and a pin that is cut when a predetermined force (the lifting force of the anchor body 1) is applied is applied to the claw connecting portion 31. It is added.
Accordingly, this embodiment is different from the second embodiment only in the configuration in which a pin is added, and elements that perform the same functions as those of the second embodiment are denoted by the same reference numerals and are described in detail. Will be omitted, and the summary will be described in detail.

As shown in FIGS. 16 to 19, the connecting member 15 on the claw body 11 side and the claw connecting portion 31 are connected by pins 50, and holes 51 for press-fitting the pins 50 are provided on both sides of the claw connecting portion 31. Each is perforated. Moreover, the hole 52 which press-fits the pin 50 is also each drilled in the both sides of the connection member 15 located in the nail | claw connection part 31. As shown in FIG.
When the pin 50 exceeds a certain pulling force, the pin 50 is cut by pulling between the claw coupling portion 31 and the claw 14 of the claw body 11 fixed by the seabed reef. Depending on the strength. As the material of the pin 50, a synthetic resin or a metal is used. In addition, when the material of the pin 50 is made of a synthetic resin, the anchor body 1 corresponding to the holding force can be provided by preparing in advance a plurality of materials having different strengths depending on the type of the synthetic resin. . Of course, even in the case of a metal, the pin 50 having a plurality of types of strength can be prepared by changing the type of material.

In the present embodiment, the claw body 11 is free with respect to the claw coupling portion 31 and the shank body 2 when the pin 50 is cut. Therefore, as shown in FIG. 19 and FIG. The holding force is not determined by the nut 41 that adjusts the spring pressure.
However, by adjusting the position of the nut 41, a spring pressure is applied to the coil spring 40, and the claw coupling part 31 is elastically biased toward the claw body 11 side, so that the claw coupling part 31 is brought into contact with the claw body 11 side. Therefore, the coil spring 40 and the nut 41 are necessary. Further, when the anchor main body 1 is pulled up, the coil spring 40 and the nut 41 are necessary to automatically return the claw main body 11 to the claw coupling portion 31 and the shank body 2 from the original state.

FIG. 21 shows a state in which the anchor main body 1 is rooted on the reef 43, and an attempt is made to pull it up in the direction indicated by the arrow a in the figure through a chain 44 connected to the anchor link 3 of the anchor main body 1. When the anchor body 1 is pulled up, a force is applied in a direction orthogonal to the axial direction of the pin 50, and when this force exceeds a predetermined value, the pin 50 is cut.
When the pin 50 is cut, a force is applied to the coil spring 40 in the direction of the arrow B in the axial direction by the spring holding portion 42 of the claw coupling portion 31, and thereby the coil spring 40 is contracted in the direction of the arrow B.

  As in the second embodiment, this means that the claw connecting portion 31 and the shank body 2 move upward with respect to the claw body 11, the connecting member 15, and the spring fixing rod 34. When the 31 and the shank body 2 are pulled up by a predetermined amount or more, as shown in FIG. 22, the connecting member 15 and the shackle 24 that are located in the claw connecting portion 31 and are connected to the claw main body 11 are exposed, and Becomes free with respect to the claw coupling portion 31 and can swing freely.

  Therefore, the claw body 11 that can freely swing with respect to the tip of the spring fixing rod 34 is detached from the reef 43, and the anchor body 1 can be pulled up as it is. FIG. 23 shows the case where the anchor body 1 is pulled up by moving the position of the ship, and the connecting member 15 of the claw body 11 becomes free with respect to the spring fixing rod 34 by pulling up with a force exceeding a predetermined level. Thus, the claw 14 of the claw body 11 is detached from the reef 43, and the anchor body 1 can be easily recovered.

  In the middle of pulling up the anchor main body 1 detached from the reef 43, the claw coupling portion 31 and the shackle 24 are moved toward the claw main body 11 with respect to the spring fixing rod 34 by the spring pressure of the coil spring 40 as shown in FIG. Since the energizing force works, while the shackle 24 and a part of the connecting member 15 are stored in the claw connecting portion 31, the front end surface of the claw connecting portion 31 comes into contact with the end surface of the nut 23 of the claw body 11. The nail body 11 automatically returns to the original position with respect to the nail connecting portion 31.

  As a result, the anchor main body 1 is rooted on the reef 43, the claw main body 11 is freely swingable with respect to the claw coupling portion 31 and the shank body 2, and the claw main body 11 is detached from the reef 43, and the anchor main body is removed. Even if 1 is pulled up, the claw body 11 automatically returns to the original position with respect to the claw connecting portion 31, so that it is not necessary to perform any work for returning the anchor body 1 to its original state after lifting the anchor body 1. For this reason, the work of getting on the bow is unnecessary, and the safety can be further improved.

When the seabed is sandy or mud and the pin 50 is not provided as in the first and second embodiments, if the spring force of the coil springs 10 and 40 is weak, the claw 14 of the anchor body 1 is Even if the nail body 11 is bent on the seabed, the nail body 11 may be bent with respect to the shank body 2, and the nail 14 may not be hooked on the seabed.
However, in this embodiment, since the pin 50 is provided, the claw body 11 does not bend with respect to the shank body 2 side so that the anchor body 1 itself is in the posture as long as the force for cutting the pin 50 is not applied. Since it maintains, the nail | claw 14 of the anchor main body 1 can be reliably hooked on the seabed.

  In this embodiment, since the pin 50 is cut and the anchor main body 1 is pulled up, unlike the first and second embodiments, the cut pin 50 is abandoned on the seabed. Therefore, unlike the conventional case where the entire anchor body 1 is abandoned, the influence on the environment is small.

  Here, after the anchor main body 1 is pulled up, a new pin 50 is press-fitted into the claw connecting portion 31 and the connecting member 15, and the claw connecting portion 31 and the connecting member 15 are connected by the pin 50.

(Fourth embodiment)
In the first embodiment, the connecting member 15 of the claw body 11 and the shank body 2 are swingably connected by the shackle 24, but the shackle is used to connect the connecting member 15 and the shank body 2. It is not limited to 24.
That is, as shown in FIG. 25, tongue-like connecting pieces 60 and 61 are integrally projected from the upper and lower ends of the end portion of the shank body 2, and one connecting piece 60 has an insertion hole 63 through which a bolt 62 is inserted. The other connecting piece 61 is provided with a screw hole 64 that is screwed with the screw portion of the bolt 62.

  The connecting member 15 is integrally formed with a connecting piece 65 positioned between the upper and lower connecting pieces 60, 61. The connecting piece 65 has a long hole 66 formed along the longitudinal direction. . And the connection piece 65 of the connection member 15 is arrange | positioned between the connection pieces 60 and 61 of the shank body 2, the bolt 62 is inserted in the insertion hole 63 of the connection piece 60, and the long hole 66 of the connection piece 65, and also bolt The screw part 62 is screwed into the screw hole 64 of the connecting piece 61.

  As a result, the bolt 62 is inserted into the elongated hole 66 of the connecting piece 65 of the coupling member 15, and the coupling member 15, that is, the claw body 11 is movable along the longitudinal direction of the elongated hole 66, and coupled with the bolt 62 as an axis. The member 15 (claw body 11) can swing with respect to the shank body 2. An arrow “a” in FIG. 25A indicates the swinging direction. In FIG. 25, the coil spring 10 is not shown.

In this embodiment, when the claw 14 of the anchor main body 1 is rooted on the seabed reef, when the anchor main body 1 is pulled up as it is with a rope, the coil spring 10 itself bends when a force greater than the urging force of the coil spring 10 is applied. At the same time, the claw body 11 is also swung, so that the claw 14 is detached from the reef and the anchor body 1 can be easily recovered.
In the middle of pulling up the anchor body 1, the coil spring 10 is returned to the axial direction by the spring force of the coil spring 10, and the claw body 11 is automatically returned to the original state with respect to the shank body 2. Therefore, there is no need for the work of lifting the anchor main body 1 after the anchor main body 1 as in the prior art and returning the claws to the original state, and the safety can be further improved.

In the present embodiment, the pair of connecting pieces 60 and 61 are provided on the shank body 2 side, and the connecting piece 65 having the long hole 66 is provided on the connecting member 15 side. The connecting pieces 60 and 61 may be provided, and the connecting piece 65 may be provided having the long hole 66 on the shank body 2 side.
Further, although the swing shaft of the connecting member 15 is the bolt 62, the connecting member 15 and the shank body 2 may be swingably connected by a pin-shaped member instead of the bolt 62.

  In this embodiment, instead of the shackle 24, the connecting member 15 is pivotally connected about a shaft rod such as a bolt 62. Therefore, when the coil spring 10 is bent, the coil spring 10 is bent or returned. Without interfering, the nail body 11 can be detached from the reef and the nail body 11 can be returned to the original state with respect to the shank body 2.

(Fifth embodiment)
In the second and third embodiments, the connecting member 15 of the claw body 11 and the spring fixing rod 34 are swingably connected by the shackle 24. However, the connecting member is the same as in the fourth embodiment. It is not limited to the shackle 24 to connect the 15 and the spring fixing rod 34.
That is, as shown in FIG. 26, tongue-like connecting pieces 70 and 71 are integrally projected from the upper and lower ends of the end portion of the spring fixing bar 34, and one connecting piece 70 is inserted through a bolt 73. The other connecting piece 71 is provided with a screw hole 74 that is screwed into the screw portion of the bolt 72.

Moreover, the structure of the connection member 15 is the same as that of 4th Embodiment. The connecting piece 65 of the connecting member 15 is disposed between the connecting pieces 70, 71, and the bolt 72 is inserted into the insertion hole 73 of the connecting piece 70 of the spring fixing rod 34 and the elongated hole 66 of the connecting piece 65, and further the bolt 72. Are screwed into the screw holes 74 of the connecting piece 71.
As a result, the bolt 72 is inserted into the elongated hole 66 of the connecting piece 65 of the coupling member 15, and the coupling member 15, that is, the claw body 11 is movable along the longitudinal direction of the elongated hole 66, and coupled with the bolt 72 as an axis. The member 15 (claw body 11) can swing with respect to the spring fixing rod 34. An arrow “a” in FIG. 26A indicates the swinging direction. In FIG. 26, the coil spring 40 is not shown.

  Since the swinging motion of the connecting member 15 with respect to the spring fixing rod 34 in this embodiment is the same as in the fourth embodiment, description thereof is omitted.

In this embodiment, the case where the pair of connecting pieces 70 and 71 are provided on the spring fixing rod 34 side and the connecting piece 65 having the long hole 66 is provided on the connecting member 15 side has been described. A pair of connecting pieces 70 and 71 may be provided, and a connecting piece 65 may be provided having a long hole 66 on the spring fixing rod 34 side.
Further, although the swing shaft of the connecting member 15 is the bolt 72, the connecting member 15 and the spring fixing rod 34 may be swingably connected by a pin-shaped member instead of the bolt 72.

  In this embodiment, instead of the shackle 24, the connecting member 15 is pivotally connected about a shaft rod such as a bolt 72, so that when the coil spring 40 bends, the coil spring 40 is bent or returned. Without interfering, the nail body 11 can be detached from the reef and the nail body 11 can be returned to the original state with respect to the shank body 2.

It is a perspective view of the anchor main body in the 1st Embodiment of this invention. (A) and (b) are the top views and front views of the anchor main body in the 1st Embodiment of this invention. It is a disassembled perspective view of the anchor main body in the 1st Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 1st Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 1st Embodiment of this invention. It is a perspective view of the anchor main body in the 2nd Embodiment of this invention. It is a top view of the anchor main body in the 2nd Embodiment of this invention. It is a disassembled perspective view of the anchor main body in the 2nd Embodiment of this invention. It is sectional drawing of the anchor main body in the 2nd Embodiment of this invention. It is sectional drawing of the anchor main body in the 2nd Embodiment of this invention. It is a principal part expanded sectional view in the 2nd Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 2nd Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 2nd Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 2nd Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 2nd Embodiment of this invention. It is a perspective view of the anchor main body in the 3rd Embodiment of this invention. It is a top view of the anchor main body in the 3rd Embodiment of this invention. It is a disassembled perspective view of the anchor main body in the 3rd Embodiment of this invention. It is sectional drawing of the anchor main body in the 3rd Embodiment of this invention. It is sectional drawing of the anchor main body in the 3rd Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 3rd Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 3rd Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 3rd Embodiment of this invention. It is explanatory drawing in the case of pulling up the anchor main body rooted in the reef in the 3rd Embodiment of this invention. (A) and (b) are the decomposition | disassembly top view and decomposition | disassembly sectional drawing in the 4th Embodiment of this invention. (A) and (b) are the decomposition | disassembly top view and decomposition | disassembly sectional drawing in the 5th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Anchor main body 3 Anchor link 6 Screw part 7 Nut 10 Coil spring 11 Claw main body 12 Center hole 14 Claw 15 Connecting member 21 Stock holding part 22 Stock 23 Nut 24 Shackle (connecting tool)
30 Screw part 31 Claw connecting part 34 Spring fixing rod 35 Screw part 40 Coil spring 41 Nut 50 Pin 62 Bolt 72 Bolt

Claims (8)

A rod-shaped shank body (2) having an anchor link (3) to which a chain or a rope is connected on one end side and a threaded portion (6) on the other end side;
A substantially W-shaped nail body (11) provided with nails (14) on the left and right,
It has a stock holding part (21) for holding the stock (22) on the distal end side, and a nut (23) is inserted through a center hole (12) drilled in the central part of the claw body (11) on the base side. A connecting member (15) fixed to the nail body (11) at
A connector (24) in which the other end and one end side of the shank body (2) are swingably connected, and a base part side and the other end side of the connecting member (15) are swingably connected;
A coil spring (10) which is inserted from one end of the shank body (2) and is attached to the shank body (2) so as to cover the connector (24);
An anchor body (1) is constituted by a nut (7) that is screwed into the threaded portion (6) of the shank body (2) and elastically biases the coil spring (10) toward the claw body (11). A two-claw anchor for boats.   The two-claw anchor for a boat according to claim 1, wherein a coil spring (10) having a spring force corresponding to a holding force is detachably attached to the shank body (2).   2. The shank body (2) and the connecting member (15) are connected in a swingable manner by a shaft rod such as a bolt (62) instead of the connecting tool (24). Bi-nail anchor for boats as described. A cylindrical shank body (2) provided with an anchor link (3) to which a chain or a rope is connected on one end side, and provided with a screw portion (30) on the inner peripheral surface on the other end side;
A cylindrical claw coupling portion (31) having one end side inserted into the shank body (2) and screwed to the screw portion (30);
A screw fixing part (34) having a screw part (35) on one end side and being arranged in the shank body (2), the other end side being located in the claw coupling part (31);
A substantially W-shaped nail body (11) provided with nails (14) on the left and right,
It has a stock holding part (21) for holding the stock (22) on the distal end side, and a nut (23) is inserted through a center hole (12) drilled in the central part of the claw body (11) on the base side. A connecting member (15) fixed to the nail body (11) at
A connector (24) in which the other end and one end of the spring fixing rod (34) are swingably connected, and a base side and the other end of the connecting member (15) are swingably connected;
A coil spring (40) disposed on the outer peripheral surface side of the spring fixing rod (34);
The claw coupling portion (31) is screwed into the screw portion (35) of the spring fixing rod (34), and the end surface of the claw coupling portion (31) is elastically urged at the tip of the coil spring (40). A two-claw anchor for boats, wherein an anchor body (1) is constituted by a nut (41) for biasing an end surface of the other end of the nut to an end surface of the nut (23).   The two-nail anchor for boats according to claim 4, wherein the nut (41) is for adjusting the spring pressure of the coil spring (40).   5. The boat two according to claim 4, wherein the connecting member (15) and the claw connecting portion (31) are connected by a pin (50) that is cut when a predetermined force or more is applied. Nail anchor.   The two-claw anchor for boats according to claim 6, wherein the strength of the pin (50) is set by the strength of the material of the pin (50). 5. The spring fixing rod (34) and the coupling member (15) are slidably coupled by a shaft rod such as a bolt (72) instead of the coupling tool (24). Or the two-claw anchor for boats of Claim 6.

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