JP4932051B1 - Submerged rubble foundation weight - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a weight for leveling a rubble foundation that solves the problem that workability of taking out an adjustment weight from a weight accommodating portion is reduced due to clogging with earth and sand and has a simple structure. .
An underwater rubble foundation leveling weight 1 provided with a weight accommodating portion 23 whose upper surface is opened so that an adjustment weight 15 for adjusting the weight can be inserted and removed freely on an outer periphery of a weight head main body 14. The weight accommodating portion 23 is a substantially rectangular parallelepiped, and one or a plurality of openings 24 that open the inside of the weight accommodating portion 23 to the outside are provided on the side surface of the weight accommodating portion 23.
[Selection] Figure 1

Description

The present invention, by Rukoto freely down to a weight for leveling water rubble basis for leveling the bottom of the water riprap plan height.

2. Description of the Related Art Conventionally, an underwater rubble foundation leveling device that forms a foundation in water by repeatedly dropping a weight suspended by a crane ship is known.
For example, as shown in FIG. 6, such an underwater rubble foundation leveling device has an upper end of a weight 1 including a weight head 2 and a pipe-like support 3 having the weight head 2 fixed to the lower end. In addition, a hanger 5 for attaching the wire 4 is provided. The wire 4 fixed to the lifting tool 5 is connected to a hoisting drum D on the ship via a pulley 6 provided at the boom tip of the crane ship C.
In addition, the code | symbol 7 in FIG. 6 is a boom raising / lowering wire, The boom raising / lowering wire 7 is wound up around the drum which is not shown in figure, or it pays out and the angle of the boom of the crane ship C is adjusted.

Then, the drum D is linked to a driving mechanism such as a motor (not shown), the wire 4 is wound up by this driving mechanism and the weight 1 is lifted, and then the lifting force is released and the weight 1 is freely dropped. The rubble 8 is leveled by the impact force when the weight 1 falls freely (see Patent Document 1). The rubble 8 is dropped in advance on the water bottom ground 9.
In the process of leveling the bottom of the water, the foundation for leveling the weight 1 by free-falling comes out from the water surface 10 in the process of leveling the bottom of the water so that it reaches the target level height h and the target size. The position of the leveling surface is detected based on the height and position of the weight 1 (see Patent Document 2).
Moreover, the said support body 3 is comprised by the some cylinder member 3a, attaches and detaches this cylinder member 3a with the water depth of the foundation which should be equalized, and adjusts the full length.

In such an underwater rubble foundation leveling device, if the weight 1 to be used is increased, the leveling operation can be completed in a short time. It is determined by the lifting capacity of the crane ship C that lifts the weight 1. In order to perform an efficient leveling operation, it is necessary to use the weight 1 that is as heavy as possible within the range of the crane boat C's lifting capacity.
The weight of the weight 1 is the total weight of the weight head 2 and the support 3. When the length of the support 3 is adjusted according to the water depth, the weight of the weight 1 changes. Therefore, when the length of the support 3 is changed in accordance with the water depth, the weight of the weight head 2 must be adjusted to match the total weight with the suspension capacity of the crane ship C.
As described above, for example, Patent Documents 3 and 4 include weights that can easily adjust the weight of the weight head 2 when the weight of the weight 1 must be adjusted.

As shown in FIG. 7, this type of weight fixes a tip of a cylindrical member 3b connected to the support 3 on the bottom plate 11 of the weight head 2, and has a predetermined interval around the cylindrical member 3b. The frame 12 made of steel plate is provided. The frame body 12 is filled with a heavy object 13 such as concrete or iron sand to constitute a head body 14.
Further, a weight case 16 for accommodating a plate-like adjustment weight 15 is provided on the outer periphery of the head body 14. The weight case 16 is a rectangular parallelepiped case having four sides surrounded by steel plates and the bottom surface closed by the bottom plate 11.

  Further, in order to facilitate the insertion / removal of the adjustment weight 15 to / from the weight case 16, the upper surface of the weight case 16 is released without providing a lid or the like, and the plate-shaped adjustment weight 15 is taken in / out from the upper surface. Then, the weight of the weight head 2 is adjusted according to the number of adjustment weights 15 put in the weight case 16, and as a result, the total weight of the weight 1 is adjusted.

Japanese Patent No. 3295809 Japanese Patent No. 3225485 No. 05-013777 JP 2000-096569 A

In the conventional submerged rubble foundation leveling device, the weight 1 whose weight is adjusted by placing the necessary number of adjustment weights 15 in the weight case 16 is lifted by the crane ship C, and then freely dropped and rubbed at the bottom 8 Repeat leveling. During this basic leveling process, the bottom sediment and pebbles rolled up by the impact of the impact of the weight 1 and the water flow enter the inside of the case from the opening on the upper surface of the weight case 16.
Such earth and sand enter not only between the wall surface of the weight case 16 and the adjustment weight 15 but also into every gap such as between the plate-like adjustment weights 15. In addition, as the weight 1 is repeatedly lifted and dropped in the foundation leveling process, the earth and sand are squeezed more and more in the weight case 16, and as a result, the sand and the like are placed in the gap in the weight case 16. It will be packed tightly in a pressed state.

If earth and sand or the like is tightly packed in the weight case 16, the adjustment weight 15 does not move, and it becomes difficult to remove the adjustment weight 15 from the weight case 16. Therefore, when the weight of the weight 1 needs to be adjusted, there is a problem that the workability of the adjustment work is poor.
Further, when the basic leveling operation is completed, the weight case 16 is emptied, and the weight head 2 and the support 3 are often disassembled and transported. However, the adjustment weight 15 is removed from the weight case 16. If time is required, the work for disassembling the weight 1 will also take time.

Moreover, just because earth and sand enter the weight case 16, sealing the weight case 16 complicates the structure for sealing, and it takes time to attach and detach the lid member for sealing. It will be frustrating.
An object of the present invention is to provide an underwater rubble foundation leveling weight that is easy to adjust the weight of the weight head, has good workability, and has a simple structure.

  The first invention is a submerged rubble foundation leveling weight provided with a weight accommodating portion whose upper surface is opened so that an adjustment weight for adjusting the weight can be inserted and removed freely on the outer periphery of the weight head main body. The weight accommodating portion is substantially a rectangular parallelepiped, and one or a plurality of openings that open the inside of the weight accommodating portion to the outside are provided on a side surface of the weight accommodating portion.

According to a second aspect of the present invention, a part of the opening is continuously provided on the bottom surface of the weight accommodating portion, and a part or all of the bottom surface is opened to the outside.
In addition, providing a part of the opening portion continuously on the bottom surface of the weight accommodating portion means that there is no member rising from the bottom surface between the bottom surface and the outside in a portion continuous with the bottom surface. It is.

According to a third aspect of the present invention, a part of the opening is continuously provided on a side orthogonal to the bottom surface of the weight housing part, and a part of the side surface of the weight housing part is opened to the outside. And
In addition, providing a part of the opening part continuously on the side perpendicular to the bottom surface of the weight accommodating part means that the part connected to the side is between the side surface connected to the side and the outside. This means that there is no member that rises from the side surface.

  4th invention presupposes 2nd invention, The inner peripheral surface of the said weight accommodating part is between the lower end of the weight for adjustment accommodated in the said weight accommodating part, and the bottom face of the said weight accommodating part. A protrusion for forming a gap opening in the opening is formed.

  In the first to fourth aspects of the present invention, since the opening part opened to the outside is provided on the side surface of the weight accommodating part into which the adjustment weight is inserted, earth and sand etc. that have entered the weight accommodating part together with the water flow from the opening part. It is discharged outside. Therefore, it is difficult for sediment to accumulate in the weight accommodating portion. If dirt or the like does not easily accumulate in the weight accommodating part, the earth and sand will not be pressed and hardened due to the fall of the weight, and the adjustment weight can be easily taken out from the weight accommodating part, and weight adjustment can be performed with good workability.

According to the second aspect of the present invention, at least a part of the bottom surface of the weight accommodating portion in which earth and sand are particularly likely to collect is opened to the outside, so that earth and sand are more easily discharged.
According to the third invention, the openings are located in the vicinity of both ends in the width direction of the plate-like adjustment weight accommodated in the weight accommodation portion, and the water flow along the plate surface of the adjustment weight is in the width direction. It becomes easy to flow out from the end. Such a flow can efficiently discharge the earth and sand that has entered between the plate surfaces of the adjustment weight to the outside.

  In the fourth invention, a gap is formed between the lower end and the bottom surface of the adjustment weight housed in the weight housing portion, and the gap is opened to an opening continuous with the bottom surface. Can be discharged more efficiently without stagnation on the bottom surface.

Further, according to the fourth aspect of the present invention, even if earth and sand are tightly packed in the weight accommodating portion, the jack is inserted into the gap between the lower end and the bottom surface of the adjustment weight from the outside via the opening. A tool such as can be inserted. In this way, if the tool can be inserted into the lower end of the adjustment weight, even if earth and sand are tightly clogged between the adjustment weights or between the side surfaces of the weight accommodating portion, the adjustment weight is difficult to move. The adjusting weight can be moved by a tool.
If even one adjustment weight moves with the tool, the clogged soil can be broken, and if one adjustment weight can be taken out, a gap will be formed. The adjustment weight can be easily taken out.

FIG. 1 is a perspective view of a weight head according to a first embodiment of the present invention. 2 is a cross-sectional view taken along line II-II in FIG. FIG. 3 is a cross-sectional view taken along line III-III in FIG. 1 and shows a state in which an adjustment weight is accommodated. FIG. 4 is a front view of a state in which the weight is accommodated in the weight accommodating portion of the first embodiment. FIG. 5 is a front view of the weight head according to the second embodiment. FIG. 6 is a diagram showing an overall configuration of a general underwater rubble foundation leveling device. FIG. 7 is a cross-sectional view of a conventional weight head.

1 to 4 show a weight head 20 according to a first embodiment of the present invention.
The weight head 20 according to the first embodiment corresponds to the conventional weight head 2 shown in FIG. And it fixes to the front-end | tip of the support body 3 which connected the some cylindrical member 3a which consists of steel pipes, and also the point which lifts and uses the support body 3 with the crane ship C as shown in FIG. is there.
Regarding the weight head 20 of the first embodiment, the same reference numerals as those in FIG. 7 are used for the same constituent elements as those in the conventional example, and the points different from the conventional example will be mainly described below.

As shown in FIGS. 1 to 3, the weight head 20 of the first embodiment forms a head body 14 by a cylindrical member 3 b, a frame body 12, and a heavy object 13 fixed on a steel plate bottom plate 11.
On the bottom plate 11, four support columns 21 made of square steel are erected along the four corners of the head body 14, and these are fixed to the bottom plate 11 by welding. The inside of these four support | pillars 21 is also filled with the heavy article 13 which consists of sand iron, concrete, etc.

  Further, four front plate members 22 surrounding the outer side of the column 21 are fixed, and four weight accommodating portions 23 are formed around the head main body 14. Each of the weight accommodating portions 23 has the same configuration, and the outer side surface 12a of the head main body 14, the side surfaces 21b and 21b of the pair of struts 21 facing each other, the front plate member 22 and its continuous plane, and the bottom plate 11 It is a substantially rectangular parallelepiped surrounded by. The top surface of the bottom plate 11 is defined as the bottom surface 11a of the weight accommodating portion 23.

1 and 2 show the state in which the weight accommodating portion 23 is empty, FIG. 3 shows a state in which the adjustment weight 15 is accommodated in each weight accommodating portion 23, and FIG. 4 shows the weight. It is a front view of the state accommodated.
1 and 2, reference numeral 27 denotes a flange for connecting the cylindrical member 3b fixed to the bottom plate 11 to the support 3 shown in FIG.

In the first embodiment, the front plate member 22 does not come into contact with the bottom plate 11, and an opening 24 is formed between the bottom plate 11a.
The weight accommodating portion 23 is surrounded not only by the front plate member 22 but also by its continuous plane. The weight accommodating portion 23 is a substantially rectangular space including a portion corresponding to the opening 24. Means that. The side surfaces 21 b and 21 b orthogonal to the bottom surface 11 a, the outer surface 12 a of the frame body, the front plate member 22, and its continuous plane are the side surfaces of the weight accommodating portion 23.

  In addition, the weight accommodating portion 23 has a dimension capable of accommodating a plurality of adjustment weights 15 in an upright manner. The width direction is set to maintain a gap with the end of the accommodated adjustment weight 15, and the vertical direction is connected to a hanging jig such as a crane on the upper end side of the accommodated adjustment weight 15. The connecting portion is dimensioned to protrude from the upper surface opening 23a.

The weight head 20 configured as described above is the same as the conventional example described above in that the weight can be adjusted by inserting and removing the adjustment weight 15 made of steel plate from the upper surface opening 23a of the weight accommodating portion 23. .
However, the weight head 20 of the first embodiment is characterized in that an upper opening 24 is provided between the lower end of the front plate member 22 that is the side surface of the weight accommodating portion 23 and the bottom surface 11a. is there.
This opening 24 is a flow of water that discharges dirt and the like that has entered the weight accommodating portion 23 from the upper surface opening 23a during the process of dropping the weight head 20 into the water and leveling the rubble, ie, the arrow shown in FIG. It is for forming the water flow along.

  Further, on the bottom surface 11a of the bottom plate 11, a pair of convex portions 25, 25 are formed with the upper surface being a curved surface along an arc with a predetermined interval. The convex portions 25, 25 support the lower end of the adjustment weight 15 accommodated in the weight accommodating portion 23. Thereby, as shown in FIG. 4, a gap 26 is formed between the lower end of the adjustment weight 15 and the bottom surface 11a.

As described above, the weight head 20 of the first embodiment is formed with the opening 24 continuous to the bottom surface 11a below the weight accommodating portion 23. Therefore, during the foundation leveling process, It is difficult to accumulate. If dirt or the like does not easily accumulate in the weight accommodating portion 23, the adjustment weight 15 will not be fixed by the earth or sand solidifying in the weight accommodating portion 23. Therefore, after completion of the basic leveling process, the adjustment weight 15 accommodated in the weight accommodation portion 23 can be easily taken out, and the workability of the work of taking out the adjustment weight 15 is improved.
In particular, since the opening 24 is continuous with the bottom surface 11a of the weight accommodating portion of the present invention and there is no member that rises at the boundary with the outside, earth and sand entering from above are easily discharged to the outside along the bottom surface 11a Accumulation on the bottom surface 11a can be prevented.

The opening 24 is formed over the entire width of the weight accommodating portion 23. That is, the opening 24 is an opening continuous with the support column 21. As described above, if the opening 24 is continuous with the support column 21, it is easy to generate a water flow that flows outward from both ends in the width direction along the surface of the adjustment weight 15 accommodated in the weight accommodating portion 23. Therefore, for example, there is an effect that earth and sand entering between the plurality of adjustment weights 15 can be easily discharged.
In the first embodiment, the side 21a of the column 21 on the front plate member 22 side is a side orthogonal to the bottom surface 11a of the present invention, and the side surface 21b of the column 21 is partially continuous with the side 21a. It is a side surface opened to the outside by the opened opening 24.

Further, in the weight head 20 according to the first embodiment, a gap 26 is formed between the lower end of the accommodated adjustment weight 15 and the bottom surface 11a by the convex portion 25 formed on the bottom surface 11a. Therefore, even if earth and sand enter between the adjustment weight 15 and the side surface of the weight storage portion 23 or between the adjustment weights 15, a tool such as a jack is inserted into the gap to adjust the adjustment weight. 15 can be moved.
Even if the earth and sand are pressed and hardened, if a tool such as a jack can be inserted into the gap 26, the adjustment weight 15 can be moved to facilitate removal.
Thus, if the adjustment weight 15 can be easily taken out, the weight adjustment workability is improved, and the weight 1 having a weight corresponding to the suspension capacity of the crane ship C can be used.

Moreover, in this 1st Embodiment, although the said opening part 24 is made into the opening which has a height of about 1/4 of the height of the support | pillar 21, the magnitude | size of an opening is not restricted to this. In order to facilitate discharge of earth and sand, it is advantageous to make the opening 24 larger. However, in order to prevent the front plate member 22 from coming off due to an impact when it is dropped freely with the adjustment weight 15 accommodated, it is advantageous to increase the connection range with the support column 21. is there.
Moreover, if the opening is too large, the adjustment weight 15 may fall off from the weight accommodating portion 23.
Therefore, the size of the opening 24 is determined in consideration of the holding weight of the adjustment weight 15, the strength, and the discharge efficiency of earth and sand.

  Moreover, in the said 1st Embodiment, the said opening part 24 is formed in the position below the weight accommodating part 23, and following the bottom face 11a and the edge | side 21a, and it is made hard to accumulate earth and sand inside. However, as long as the inside of the weight accommodating portion 23 can be opened to the outside, the position where the opening 24 is formed is not limited to the first embodiment.

Furthermore, although a pair of convex part 25 is formed in the bottom face 11a, this convex part 25 is not an essential component.
In 1st Embodiment, although the upper surface of the said convex part 25 is made into the curved surface along a circular arc so that earth and sand etc. may not accumulate on it, the shape is not restricted to this embodiment.
As long as a gap can be formed between the adjustment weight 15 accommodated in the weight accommodating portion 23 and the bottom surface 11a, the convex portion may have any shape and may be provided at any position. For example, the convex portion 25 may be provided anywhere in the weight accommodating portion 23 such as the outer side surface 12a and the side surface 21b of the frame 12 instead of the bottom surface 11a. However, the shape and installation location where the convex portion 25 prevents the flow of water for discharging soil and the like are not preferable.

FIG. 5 is a front view of the weight head 30 according to the second embodiment.
In addition, about the same component as the weight head 20 of the said 1st Embodiment, the code | symbol same as what was used in the said 1st Embodiment is used, and the description about each component shall be abbreviate | omitted.
The weight head 30 of this embodiment uses three bar members 28a, 28b, and 28c instead of the front plate member 22 of the first embodiment. These rod members 28a, 28b, and 28c are fixed between a pair of support columns 21 and 21 with a predetermined interval therebetween to constitute a weight accommodating portion 23. Thus, an opening 24a, an opening 24b, and an opening 24c are formed between the bottom surface 11a and the rod member 28a, between the rod members 28a and 28b, and between the rod members 28b and 28c, respectively. The

As described above, the weight head 30 is formed with three openings 24 a, 24 b, and 24 c that open the inside of the weight accommodating portion 23 to the outside on the side surface of the weight accommodating portion 23. These openings 24a, 24b, and 24c make it difficult for dirt and the like to accumulate in the weight accommodating portion 23.
Further, similarly to the first embodiment, a convex portion 25 is formed on the bottom surface 11a, and a gap 26 is formed between the lower end of the accommodated adjustment weight 15 and the bottom surface 11a.
For this reason, for example, even if a plurality of adjustment weights 15 are accommodated and soil is clogged between the adjustment weights 15 and the adjustment weight 15 becomes difficult to move, a tool is inserted into the gap 16 to adjust the adjustment weight 15. Can be moved.
Therefore, if the weight for leveling the submerged rubble using the weight head 30 of the second embodiment is used, the weight of the weight 1 can be adjusted with good workability in accordance with the suspension capacity of the crane ship C. Can do.

Also in the second embodiment, the convex portion 25 provided on the bottom surface 11a may be provided other than the bottom surface 11a as long as it is an inner peripheral surface of the weight accommodating portion 23, or may be omitted. Moreover, what kind of shape may be sufficient as the convex part 25. FIG.
And if the outer surface of the weight accommodating part 23 is comprised by several members like bar member 28a, 28b, 28c like this 2nd Embodiment, several opening parts can be provided in one side surface. The earth and sand in the weight accommodating portion 23 can be more easily discharged.
The thickness and number of the rod members 28a, 28b, 28c may be adjusted within a range in which the strength can be maintained.

Further, as described above, in order to discharge earth and sand from the weight accommodating portion 23, the opening that opens the inside of the weight accommodating portion 23 to the outside is not limited to the first and second embodiments, and is formed in any way. May be.
For example, instead of the front plate member 22 of the first embodiment, a perforated panel having a large number of communication holes on the entire surface, or a mesh-like member can be used.
Furthermore, as long as the adjustment weight 15 can be prevented from falling off, most of the side surfaces may be openings.

Furthermore, the weight accommodating part 23 should just be provided around the said head main body 14, and the formation method is not limited to the said embodiment. For example, a rectangular parallelepiped member individually formed of a steel plate may be fixed on the bottom plate 11 as a weight accommodating portion, and the support column 21 is not essential.
In the first and second embodiments, the four weight accommodating portions 23 that surround the four sides of the head main body 14 are provided. Therefore, the number of adjustment weights 15 accommodated in each weight accommodating portion 23 is equalized and overlapped. The weight 1 can be balanced.

Further, a plate-like adjustment weight 15 is stood and accommodated in the weight accommodating portion 23, and its insertion / removal is performed with the adjustment weight standing.
As described above, since the adjustment weight 15 is accommodated in an upright state, the bottom area of the weight accommodation portion 23 is limited, and the upper opening 23a has a small margin for the thickness of the plurality of adjustment weights 15. The required size is sufficient.
As described above, the adjustment weight 15 is stood and accommodated, so that the upper opening 23a can be minimized, and the resistance of water acting on the adjustment weight 15 when the weight 1 moves up and down is also placed on the plane. Therefore, the adjustment weight 15 can be prevented from jumping out of the weight accommodating portion 23.

  As described above, the weight heads 20 and 30 according to the first and second embodiments can adjust the weight of the weight 1 in accordance with the suspension capacity of the crane ship C with good workability. Thus, if the weight adjustment of the weight 1 is easy, it is easy to adjust the weight to the full capacity of each crane ship C to be used. If the weight of the weight 1 is increased, the basic leveling work can be performed in a short time. In other words, the weight adjustment is facilitated, so that the work efficiency of the underwater rubble foundation leveling work is improved.

  The weight of the present invention can improve the working efficiency of underwater rubble foundation leveling work.

DESCRIPTION OF SYMBOLS 1 Weight 11 Bottom plate 11a Bottom surface 14 Head main body 15 Adjustment weight 20 Weight head 21 Column 21a Side 21b (perpendicular to bottom surface) Side surface 22 Front plate member 23 Weight accommodating portion 23a Top surface opening 24 Openings 24a to 24c Opening 25 Convex part 26 Crevice 28a-28c Bar member 30 Weight head

Claims (4)

  An underwater rubble foundation leveling weight provided with a weight accommodating portion whose upper surface is opened so that an adjustment weight for adjusting the weight can be inserted and removed freely on the outer periphery of the weight head main body. An underwater rubble foundation leveling weight having a rectangular parallelepiped shape and one or a plurality of openings that open the inside of the weight accommodating portion to the outside on the side surface of the weight accommodating portion.   2. The weight for leveling a submerged rubble stone according to claim 1, wherein a part of the opening is continuously provided on the bottom surface of the weight accommodating part, and a part or all of the bottom surface is opened to the outside.   3. The underwater according to claim 1, wherein a part of the opening is continuously provided on a side orthogonal to the bottom surface of the weight container, and a part of the side surface of the weight container is opened to the outside. Weight for foundation leveling.   On the inner peripheral surface of the weight accommodating portion, a protrusion for forming a gap that opens to the opening is formed between the lower end of the adjustment weight accommodated in the weight accommodating portion and the bottom surface of the weight accommodating portion. The weight for leveling a foundation for underwater rubble according to claim 2 formed.

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