KR101814204B1 - Chain arresting device - Google Patents

Abstract

The present invention relates to a chain restraining device for an anchor chain comprising guiding means (14a, 14b, 15) for chain links (5, 9) and being actuated by a windlass. The chain constraining element 2 operates between a first position remote from the chain links, a second position in contact with the chain links in a non-arresting state, and a third position in contact with the chain links in the constrained state can do. The chain restraining element 2 comprises at least one first contact means 23a and 23b for contacting the first chain link 9 and a second contact means 23a and 23b for the corresponding contact means 10a and 10b which are stopped in the chain restraining device Further comprising at least one second contact means (19a, 19b) for contacting.

Description

{Chain arresting device}

The present invention relates to an apparatus for controlling movement of a chain. More specifically, the present invention relates to an apparatus of a first-term introduction unit for capturing and restraining movement of an anchor chain.

There is a tendency to anchor vessels far away from ships at sea (away from harbors and sheltered waters) as compared to the past. This tendency can be caused by the economic and / or operational advantages of the owner or skipper, in addition to the fact that the congestion of the ports around the world is increasing.

If the vessel is anchored off the port to a body of water exposed to considerable wave forces, the anchor system of the vessel may be exposed to unexpected dynamic loads at design time. A typical anchor winch system is designed to lift anchor and anchor chains from a depth of about 80 to 100 meters (7 to 10% of the chain breaking load) at a speed of 9 meters per minute. Special problems in open waters can cause severe swells when lifting the anchor, resulting in loads greater than those designed for anchor locations and auxiliary equipment. The load can be increased by resistance by seabed soil attached to the anchor fluke. As a result, the anchor winch is exposed to loads that exceed the winch's capacity, the hydraulic motor that powers the winch fails, and the anchor chain begins to sink into the ocean without control. In addition, the hydraulic system is subject to irreparable damage. This situation makes the safety of the ship and crew dangerous. Chain stoppers are used to restrain the anchor when the anchor is lowered and thus to mitigate the anchor windlass on the vessel when the vessel is anchored. Commonly used chain stoppers include an open slideway that supports the horizontal link of the chain in parallel with the slide way and provides a guide groove for the vertical link of the chain.

The prior art disclosed in document GB 1 592 884 is that when a ship is anchored or anchored to an anchoring buoy, such as a chain stopper to release the anchor winch, And chain stoppers for restraining an anchor chain to be used. The chain stopper includes constraints locking engagement or departing from a horizontal chain link.

The prior art disclosed in the document EP 0 379 848 B1 relates to a chain stopper for tightening an anchor chain so as to maintain a close contact state with an anchor chain when the anchor is in the inserted position. The chain stopper includes a slide way having a guide groove in which an anchor chain is guided when an anchor is lowered and raised. The support is strongly attached to the frame of the chain stopper and extends upwardly from the frame so that the support pivotally supports and supports a chain tightening means which can be extended and retracted. Wherein said support is provided with an operating position in which said chain tightening means makes contact with a chain link of an anchor chain in a power operating state in said guide groove, And can be pivoted between the non-actuated positions formed.

In other known chain stoppers, a restraining action is formed through a rigid bar that descends, for example, in the transverse direction of the anchor chain to restrain the chain link perpendicular to the abutment. Thus, according to the prior art disclosed in JP 10059272, the control device of the anchor chain includes the frame having the guide member composed of the guide roller and the guide groove for guiding the movement of the anchor chain. An axis is installed on both sides of the frame in the same direction as the direction of motion of the anchor chain. A stopper slides on the shaft and rotates in a direction transverse to the direction of movement of the anchor chain.

Applicants present the present invention to solve the above problems and to seek another advantage.

The present invention is disclosed in the main claims and features of the present invention are presented, and the dependent claims describe other features of the present invention. Accordingly, the present invention comprises a chain restraining device for an anchor chain comprising guiding means for chain links and operated by a windlass, comprising a first position apart from the chain links, a non-arresting state A chain restraining element operable between a second position in contact with the chain links to the first chain link and a third position in contact with the chain links in the restrained state, Further comprising at least one first contact means and at least one second contact means for contacting the contact means stopped in the chain restraining device.

According to an embodiment of the present invention, there is provided a guide device comprising: a guide groove for sliding connection with a first chain link; and first guide surfaces for sliding connection with a second chain link, And a contact surface of an inclined structure.

It is preferred that the chain restraining element includes a support surface for sliding contact with the first chain link when the chain passes through the chain restraining device. According to one embodiment of the present invention, the support surface further comprises a wear element.

According to one embodiment of the present invention, the chain restraining element further comprises a counterweight rotatable about a fulcrum between the first, second and third positions and capable of pivoting about the fulcrum by a lever The load of the chain restraint element can be selectively increased or decreased.

 Advantageously, said chain restraining device further comprises a discharge opening for fluidly interchanging with the lower region of said third contact means.

A chain restraint device according to the present invention is capable of capturing and restraining an anchor chain (which automatically begins to slip out of the winch, for example, during lifting of the anchor) for a very short period of time - Is prevented from being delivered to winches (e.g., anchor winch motors and ancillary equipment), and anchoring chains are prevented from entering the water in an uncontrolled state.

The chain restraining device according to the present invention is also characterized in that the chain restraining device according to the present invention is also characterized in that when the anchor is placed at the position where it is inserted into the hull of the ship or when the anchor is installed at the sea floor or when the ship is anchored to buoy, It can be used as a chain stopper.

The chain restraining device according to the present invention can be assembled to a ship of the prior art, thereby avoiding an increase in the cost of winch equipment such as anchor winch and hydraulic motor.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and other features of the present invention will become more apparent from the following description of preferred embodiments, which refers to the accompanying drawings, but does not limit the invention.

1 is a perspective view showing an embodiment of a chain restraining device according to the present invention;
Fig. 2 is a perspective view similar to Fig. 1 and similar to Fig. 1, with the components of the chain restraining device shown and shown in line to illustrate some of the components within the chain restraining device.
Figure 3 is a perspective view, with some of the components removed and showing a portion of the chain restraint device in close proximity;
Figure 4 is a perspective view showing a first embodiment of a chain restraining element (pawl) for a chain restraining device.
Figure 5 is another perspective view of a chain restraining device with some components removed.
Fig. 6 is a side view showing the components of the chain restraining device shown in line and showing a portion of the chain restraining device to show some of the components inside the chain restraining device. Fig.
Fig. 7 is a view similar to Fig. 6, showing movement positions of a counter weight. Fig.
Figs. 8-12 illustrate various steps relating to the operation of the chain restraining device and are perspective views illustrating a second embodiment of the restraining pawl. Fig.
13 is a perspective view showing a restraining element arranged in a chain restraining position;
Fig. 14 is an enlarged view of a restraining element arranged in the chain restraining position as seen from the side; Fig.
15 and 16 are side views showing the effect of the angle of the contact surface.
Fig. 17 is a perspective view of the chain restraining device showing the chain restraining device in its inoperative position, i.e. when the restraining elements pawl are lifted away from the other chain; Fig.
18 is a side view schematically illustrating an embodiment of a restraining element comprising fingers with an outer side forming an angle;

1 and 2, the chain restraint device of the present invention comprises two upright plate elements 4a, 4b in the illustrated embodiment, the upright plate elements 4a, 4b are attached at their lower ends onto the deck of the ship (not shown in the drawings) according to the prior art. The chain restraining device can be welded to the deck between a winch and a hawse pipe by replacing a prior art chain stopper. The anchor chain 16 (only a portion of which is shown) moves along the arrow I into the hull towards the winch (not shown) (not shown) and moves to the outside of the hull Move along arrow (O). Accordingly, when the anchor chain is discharged to the outside of the hull, the anchor chain moves in the direction of the arrow O, whereas in relation to the operation of lifting the anchor, for example, when the anchor chain is pulled inward, . The above-described operations known as the prior art are not further described.

The anchor chain 16 comprises a plurality of individual chain links, which are arranged alternately approximately perpendicular to each other by conventional techniques. A chain link 5 that is upright or substantially vertical and a chain link 9 that is substantially horizontal in a prone state are shown. For purposes of illustration, the directions of the chain links are not strictly horizontal or vertical, but are referred to as vertical chain links 5 and horizontal chain links 9.

The chain restraining device also includes a guide roller 12 for changing the direction of the chain according to a predetermined method. The guide rollers known in the prior art (referring to Fig. 5) include vertical support surfaces for the vertical chain links 5 and horizontal chain links 9 in the illustrated embodiment. The guide roller also includes other known design structures with several "pockets" for the chain links.

In addition, the chain restraining device comprises guide surfaces 14a, 14b for the horizontal chain links 9 and vertical chain links (not shown) for stopping the chain guide parts, more precisely (referring to Figures 3 and 5) 5). ≪ / RTI >

The chain restraining pawl 2 is rotatably supported by the rotary part 2b in the support part 2a of the coinciding structure inside the upright plate elements 4a and 4b. Thus, the chain-restraining element 2 is arranged on the chain, as shown in, for example, Figures 2, 7 and 8, from an inoperative position raised from the chain (referring to Figure 17) Can be rotated up the operation. The chain restraining element 2 further comprises a rotatable lever 3 with a counterweight 7 attached to the free end of the chain restraining element 2. The lever 3 can be rotated to adjust the load applied by the chain restraining element 2 onto the anchor chain. Referring to Figures 2 and 7, an example of two end positions about 180 degrees apart is shown. Referring to Fig. 7, the position at which the chain restraining element 2 exerts the maximum load (provided by the counterweight) with respect to the chain is shown. Referring to Figure 2, another end position is shown where the load applied to the chain is relatively small. When the lever 3 is arranged in the position of FIG. 2, the lever is used as a handle and the user lifts the chain restraining element to the inoperative position.

4, the chain restraining element 2 further comprises two fingers 17a and 17b. Between the fingers 17a and 17b, the fingers form a hole 21 for receiving the vertical chain links 5 (shown in Fig. 5). Each of the fingers 17a and 17b has a chain contact surface 23a and 23b for contacting the horizontal chain link 9 when the chain locking element 2 is arranged in the chain restraining position And sliding surfaces 20a, 20b which are in sliding contact with the upper side of the horizontal chain links 9 when the chain is pulled into the winch. The following description of the function of contact surfaces 19a, 19b and contact surfaces 19a, 19b is provided.

According to an alternative embodiment, the support surfaces 20a, 20b have individual wear elements 22a, 22b as shown in Fig. The wear elements 22a, 22b, which may be made of a synthetic material such as nylon, reduce friction between the chain constraint elements of the metal and the chain links, thereby reducing wear and shear between the elements, . When the chain restraining elements 2 are arranged in an operating position (i.e., arranged on a chain) so that the anchor chain starts sliding in the direction of "O ", the fingers of the chain- The risk of damaging the link is reduced by the support surfaces 20a, 20b and the wear elements 22a, 22b.

3 and 5, which illustrate a chain guide guiding portion, each guide surface 14a, 14b has a contact surface 10a, 10b of a groove structure. The contact surfaces 10a, 10b are designed to coincide with the contact surfaces 19a, 19b of the chain restraining elements and to provide a stationary support for the chain restraining elements. The discharge openings 6a, 6b shown in Figures 3 and 5 are aligned in the lower region of the contact surfaces 10a, 10b (see Figure 14). Thus, mud and fine clay, which can be attached to the chain, are conveniently discharged from the chain restraining device through the discharge opening. The venting action is reinforced through the contact surfaces 19a, 19b of the chain restraining element being pressed against the contact surfaces of the groove structure by the action of the chain.

The operation of the chain restraining device according to the present invention can be conveniently distinguished as follows.

a) a non-operational mode (see FIG. 17) in which the chain restraining element 2 is lifted off the chain (for example, the anchor chain is paid out)

b) a stand-by operating mode when the anchor chain is pulled inward towards the winch and the chain restraining element slides on the horizontal chain links 9,

c) an arresting state when the anchor chain starts slipping out of the winch and the chain restraining element is connected to the horizontal chain link 9,

d) When the anchor chain is in a static state, that is, when the anchor is arranged at a stowed position with respect to the hull, when the anchor is installed on the sea bed, or when the ship is anchored or floated, Operating mode.

Referring to Figures 8 to 13, the following description is mainly provided regarding the atmospheric and restrained state operation modes.

Figure 8 shows a variant of a chain restraining element without wear elements and Figures 9-12 show a variant with wear elements 22a, 22b. However, the following description of operation applies to both variants. Fig. 8 shows a state in which it is pivoted away from the chain restraint element as described above. 9 to 12 show a case in which the lever 3 and the counterweight 7 are pivotally rotated toward the chain restraining element to apply a relatively large load to the chain restraining element. Although the positions of the levers shown in Figs. 9 to 12 are preferred because they provide relatively fast restraint, the following description applies in principle to both positions of the levers.

8 and 9 show a state in which the anchor chain is pulled toward the unwanted ("I" direction) and the fingers of the chain restraining element 2 slide on the horizontal chain link 9 as described above . In this state, the chain restraining device is in the standby state operating mode following the movement of the chain.

10 is a view showing a state in which the load acting on the chain is larger than the pulling load of the winch (due to the swells described in the background art and the like) and the direction in which the anchor chain is directed to the hawse pipe (the "I" And starts to move toward the outside. The fingers 17a and 17b of the chain restraining element start to slide from the horizontal chain link 9.

Referring to Fig. 11, the state shown in Fig. 10 further advances and the fingers of the chain restraining element are away from the horizontal chain link 9. Fig. The succeeding vertical chain link 5 can be passed through the hole 21 without interfering with the chain restraining element.

12 shows that as the chain further moves in the "I" direction, the fingers come into contact with the next horizontal chain link 9 'along the chain link 9 and the contact surfaces 19a, 14b, 14a, 14b, respectively. Thus, Figure 12 shows the chain when the chain is fully restrained by the chain restraining device. The same state shown in Fig. 12 is shown at different angles in Fig. 13, and the manner in which the chain contact surfaces 23a, 23b of the fingers contact the horizontal chain link is shown. According to the above description, it is assumed that the chain restraint element is automatically unfastened assuming that the winch is pulled into the anchor chain, and that the chain restraint element is assumed to be in the sliding position on the horizontal chain links and is in the standby state operating mode .

A fully fixed state is shown schematically in Figs. 15 and 16. Fig. 15 and 16 show the effect of the rake angle of the contact surfaces 19a, 19b, 10a and 10b. The load F _R formed by the anchor chain of the chain fastening device is shown by the arrow and the load components F _A and F _B of the load are shown.

Fig. 15 shows the first rake angle alpha ₁ , and the chain restraining element is a straight structure. Figure 16 shows the first rake angle alpha ₂ and the outer ends of the chain restraining elements, with the contact surfaces 19a, 19b having a brake angle beta against the rest of the chain restraining elements. Thus, the contact surfaces 19a, 19b, 10a, and 10b shown in FIG. 16 are formed so as to be steeper than the contact surfaces 19a, 19b, 10a, and 10b shown in FIG. 15, that is,? ₁ >? ₂ . Therefore, it is preferable to have a relatively steep rake angle (alpha _{2 in} Fig. 16) and a brake angle beta > 0 so as to generate a relatively small load F _A relative to the rotating portion 2b of the chain- Because. This structure is preferred in terms of structural design. Therefore, the rake angle alpha and the brake angle beta of the chain restraint element can be optimized such that the load of the anchor chain is mainly accommodated by the contact surfaces 10a and 10b. Fig. 18 shows a brake angle? As a close-up schematic view of a modified example of the chain restricting element.

2 .... chain constraint elements,
3 .... Lever,
4a, 4b .... upstanding plate element,
5,9 .... chain link,
7 .... Counterweight,
15 .... guide grooves,
17a, 17b .... fingers,
19a, 19b .... contact surface,
20a, 20b .... supporting surface

Claims (6)

(14a, 14b, 15) for the chain links (5,9) and having a first position apart from the chain links, a second position contacting the chain links in a non-arresting state, 1. A chain restraining device for an anchor chain operated by a windlass comprising a chain restraining element (2) operable between a third position in contact with the chain links in a state,
The chain restraining element 2 is provided with at least one first contact means 23a and 23b for contacting the first chain link 9 and corresponding third contact means 10a and 10b which are stopped in the chain restraining device And the third contact means (10a, 10b) further comprise at least one second contact means (19a, 19b) And the chain constraining element 2 is pivotally rotated about the fulcrums 2a, 2b between the first position, the second position and the third position,
The chain restraining element 2 comprises a counterweight 7 which is pivotally rotated about the fulcrums 2a and 2b and attached to the free end of the lever 3 to adjust the load applied by the chain restraining element 2 onto the anchor chain, A first position at which the lever 3 and the counterweight 7 are pivoted toward the chain restraint element 2 so as to apply a maximum load on the anchor chain by the counterweight 7 and a second position at which the lever 3 ) Is pivoted away from the chain restraint element (2) and applies a load less than the maximum load on the anchor chain and is used as a handle to allow the user to lift the chain restraint element (2) to the first position Is pivotable about said support points (2a, 2b), said second position being 180 degrees away from said first position. 2. The slide fastener according to claim 1, further comprising a guide groove (15) for sliding connection with the first chain link (9) and a first guide surface (14a, 14b) for sliding connection with the second chain link (5) Characterized in that the contact means (10a, 10b) comprise a contact surface of an inclined structure in one or more recessed portions of the guide surfaces (14a, 14b). The chain restraint element (2) according to claim 1 or 2, wherein the chain restraining element (2) comprises support surfaces (20a, 20b) for sliding contact with the first chain link (5) Wherein the chain restraining device is a chain restraining device. 4. The chain restraint device of claim 3, wherein the support surfaces (20a, 20b) further comprise wear elements (22a, 22b). 3. Chain restraint device according to claim 1 or 2, further comprising discharge openings (6a, 6b) for fluid exchange with the lower region of the third contact means (10a, 10b). delete

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