JPH0214244Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to an improvement of an underwater cable feeding device.

[Prior Art and Problems] When laying an underwater cable, it is necessary to lay the cable from a laying ship to the underwater bottom with a predetermined cable tension while applying a braking force to the cable.

However, conventionally, as shown in Fig. 3, a tension measuring device C' is provided between the cable feeding guide A' at the stern and the cable brake device 4', and the cable tension is measured by this tension measuring device C'. The cable braking force is adjusted by operating the brake device 4' to adjust the cable tension to a predetermined tension.

Conventionally, the cable tension measuring device described above uses a three-point tension meter in which one movable rotating sheave with a tension meter is placed between two fixed rotating sheaves. . In this case, in order to avoid applying excessive bending strain to the cable, the distance between the supports at both ends usually needs to be at least 4m, and in the case of a small ship with limited space, it is difficult to secure such a wide distance between the supports. Therefore, there is a risk that excessive bending strain will be applied to the cable. In addition, the cable is subjected to friction between the tension meter and the cable feeding guide at the stern, and if this frictional force is f ₀ and the tension when the cable is put into the water is f ₁ , then the tension can be measured by the tension meter. Tension is f ₀ +
f ₁ , and there is also a problem that the true installed cable tension f ₁ cannot be measured.

[Purpose of the invention] The purpose of the invention is to provide an underwater cable feeding device that can measure the true cable installation tension and lay the cable at a predetermined tension without applying excessive bending strain to the cable. be.

[Structure of the invention] The underwater cable feeding device according to the invention is provided with a cable feeding guide having an arcuate cable guide surface section at the stern of an underwater cable installation ship, and a cable to which a braking force is applied is guided to the cable feeding device. - In an underwater cable feeding device in which the cable is laid on the bottom of the water through a bull feeding guide, the cable feeding guide has an arc-shaped cable guide surface portion whose cable guide width becomes wider as it reaches the tip, and a cable guide surface portion that is connected to both ships. It consists of a guard section erected along the
A rectangular hole is bored at the base end on the narrow side of the cable guide surface portion, and the hole has an arcuate cable guide portion sized to loosely fit into the hole. In addition, a substantially central lower end portion of the cable guide portion is pivoted so as to rotate in the cable feeding direction, and this pivot portion is fixed to a cable guide surface portion having one end located on the proximal end side of the rectangular hole. A movable guide member connected to the other end of a movable arm rotatably supported by a frame for use is arranged, and a load cell is disposed at the lower end of the movable pivot portion of the movable guide member. This is a characteristic configuration.

[Explanation of Examples] The present invention will be explained below with reference to the drawings.

FIG. 1 shows a schematic installation diagram of the underwater cable feeding device according to the present invention. In the figure, 1 is a laying ship, and in addition to a self-propelled ship, a barge can also be used. 2
is a cable feeding guide equipped with an arc-shaped cable guide surface section, and is installed at the stern of a laying ship. Reference numeral 3 denotes a tension measuring means, which is composed of a movable guide member and a load cell, as will be described later. 4 is a cable brake device.

FIG. 2A is a front view showing the cable feeding guide, FIG. 2B is a sectional view taken along line bb in FIG. 2A, and FIG. 2C is a sectional view taken along line cc in FIG. 2A.
FIG.

In FIGS. 2A to 2C, reference numeral 51 denotes an arc-shaped guide plate for guiding the laid cable. is wide.

Reference numeral 52 denotes guard portions erected along both sides of the guide plate to ensure that the installed cable passes over the guide plate 51.

A rectangular hole B is bored at the base end on the narrow side of the guide plate 51.
A movable guide member, which will be described later, is arranged.

A is a movable guide member having an arcuate cable guide portion sized to loosely fit into the rectangular hole B, and the cable guide portions of the movable guide member A include both side plates 53, 53.
A roll having a large number of rolls 54, . . . arranged in an arc shape can be used.

Both side plates 53, 53 are pivotally supported by a spacer shaft 55 at their central lower ends, and are rotatable in the cable feeding direction using the spacer shaft 55 as a fulcrum.

Both ends of the spacer shaft 55 are connected to a guide plate 5, one end of which is located on the base end side of the rectangular hole B.
1 is pivotally supported by a fixed frame 50, and is connected and supported by the other ends of movable arms 56, 56 which are rotatable about this pivot portion 57 as a fulcrum,
Therefore, the roll group 54 disposed on both side plates 53, 53, that is, the arc-shaped cable guide portion, is movable in the vertical direction (in the direction of moving in and out of the so-called hole portion) while rotating in the cable feeding direction. It is composed of

In FIG. 2C, 58 is a cover with a low friction coefficient that is placed over the spacer shaft 55.

In FIGS. 2A to 2C, 59 is a load cell incorporating a strong gauge, which is disposed at the lower end of the movable shaft support portion of the movable guide member A;
The movable guide member A is supported by the low friction cover 58 on the pressure receiving plate 591 . 592
is a water drainer for protecting the load cell 59 from flooding. This load cell 59 measures the laying tension of the cable passing through the cable guide section of the movable guide member A based on the amount of vertical movement of the cable guide section.

Note that a roll may be used instead of the guide plate 51 described above.

In the above, when the cable passes through the arcuate cable guide surface of the cable feeding guide 2 with a tension T, a lateral pressure P which is a function of the radius of curvature R of the guide surface and the tension T acts on the guide surface, causing a circular arc in the movable guide member A. The arc angle of the arc cable guide part is θ
Then, a load that is a function of the lateral pressure P and the arc angle θ acts on the load cell 59. Since the radius of curvature R of the guide surface and the arc angle θ of the movable guide member A are known, the cable tension T can be easily measured by the load cell 59.

Due to friction with the cable, a minute amount of tensile force acts on the arc-shaped cable guide portion of the movable guide member A, as shown by arrow F in FIG. However, such movement can be prevented by the presence of the movable arm 56.

[Effects of the invention] As described above, the underwater cable feeding device according to the invention has a cable feeding guide that feeds out a cable to which a braking force is applied, and a cable guide surface portion in the shape of an arc whose cable guide width increases toward the tip. A rectangular hole is formed at the base end on the narrow side of the cable guide surface, and a guard section is provided upright along both sides of the cable guide surface. A movable guide member having an arc-shaped cable guide portion sized to fit therein is arranged so as to be movable in the vertical direction (in the direction of moving in and out of the so-called hole portion) while being rotated in the cable feeding direction. Since the structure is such that a load cell is installed at the lower end of the movable shaft support part of the member, it is possible to use the arc-shaped cable feeding guide used when laying underwater cables without separately installing a tension measuring device as in the past. The cable tension can be measured by using only a portion of the cable, that is, in the optimum state where no further frictional force is generated on the cable immediately before being put into the water, and the true cable tension can be determined.

In addition, a dedicated space for installing the cable tension measuring device is not required, and a small-sized laying ship is sufficient, making it possible to reduce the cost of laying the cable, making it economical.

Furthermore, the movable guide member for measuring cable tension is arranged in a rectangular hole bored on the narrow side of the cable guide surface of the cable feeding guide, and guard parts are provided on both sides of this hole. Since it is installed upright, not only can the cable whose tension is to be measured be brought into contact with the movable guide member reliably, but also the movable guide member itself can be made compact and lightweight to the minimum necessary, improving the accuracy of tension measurement values. It's quite possible.

Furthermore, even if a tensile force due to friction with the cable acts on the movable guide member during measurement and the movable guide member attempts to move in the cable installation direction, such movement will occur if the spacer shaft that rotatably supports the movable guide member is in the hole B. This is prevented because it is connected and supported by a movable arm that is pivotally supported by a frame for fixing the guide plate located on the base end side of the guide plate.

[Brief explanation of the drawing]

Fig. 1 is an explanatory diagram showing the installation outline of the underwater cable feeding device according to the present invention, Fig. 2 A is a front view showing the cable feeding guide used in the present invention, and Fig. 2 B is b in Fig. 2 A. -b sectional view, second
FIG. C is a sectional view taken along the line CC in FIG. 2A, and FIG. 3 is an explanatory diagram showing a conventional underwater cable feeding device. In the figure, 1 is an underwater cable laying ship, 2 is a cable feeding guide, 3 is a tension measuring means, 4 is a cable brake device, 50 is a frame, 51 is an arc-shaped guide plate, 52 is a guard part, 53 is a side plate, 54 is a roll, 55 is a spacer shaft, 56 is a movable arm, 57 is a shaft support portion, 58 is a cover with a low friction coefficient, 59 is a load cell, 591
592 is a pressure receiving plate, and 592 is a drainer.

Claims (1)

[Scope of utility model registration request] An underwater cable feeding device in which a cable feeding guide with an arcuate cable guide surface portion is provided at the stern of an underwater cable laying ship, and a cable to which a braking force has been applied is passed through the cable feeding guide and laid on the underwater bottom, The cable feeding guide is composed of an arc-shaped cable guide surface portion whose cable guide width becomes wider toward the tip, and guard portions erected along both sides of the cable guide surface portion. A rectangular hole is drilled at the base end, which is the narrow side, and the hole includes:
It has an arcuate cable guide portion sized to loosely fit into this hole, and a lower end portion of the approximately central portion is pivotally supported so as to rotate this cable guide portion in the cable feeding direction, and this pivot portion A movable guide member having one end connected to the other end of a movable arm rotatably supported by a frame for fixing the cable guide surface located on the base end side of the rectangular hole, and An underwater cable feeding device characterized in that a load cell is disposed at the lower end of a movable shaft support portion of a guide member.