KR20220025331A - Hydraulic hammer - Google Patents

Abstract

The present invention relates to the verticality holding device of a hydraulic hammer device for driving piles in deep sea. The inventor who invented the hydraulic hammer device for driving piles in deep sea (Korean Patent Registration No. 10-2111790) provided a technique for driving piles by using a hydraulic hammer with a clamped pile, while the hammer is located on the seabed. However, the problem is that when a wire installed in a crane is released, the hammer device connected to the wire goes underwater, and a pile being operated by the hydraulic hammer device has to dig itself vertically toward the seabed, but when the wire is loose, the hammer device does not maintain a vertical position and tilts, thereby making it impossible to drive piles or causing inefficient work. To solve the problem, the present invention provides a verticality holding device (1) for maintaining a vertical position of a hydraulic hammer device. The verticality holding device comprises: both slide rails (4, 4a); both slide members (5, 5a); a horizontal member (10); and a hydraulic hammer device (20) connected by hinges (11).

Description

Vertical retaining device of hydraulic hammer device for driving deep sea piles {Hydraulic hammer}

The present invention relates to a vertical holding device for a deep-sea pile driving hydraulic hammer device, and the present inventors have disclosed the deep-sea pile driving hydraulic hammer device of Korean Patent Registration No. 10-2111790 No. 10-2111790.

As the inventor, he provided a technique for driving a pile using a hydraulic hammer clamping a pile at the bottom of the deep sea corresponding to the depth of the water.

However, the problem is that when the wire installed in the crane is released, the hammer device connected to the wire goes down under the water, and then the pile being operated by the hydraulic device is deep and has to dig vertically down to the bottom.

If the wire is loose, the hammer device does not maintain verticality and tilts, making pile driving impossible or inefficient in workability.

In order to solve the above conventional problems, the present invention is to provide a vertical holding device (1) for holding the hydraulic hammer device vertically.

In general, seaweed is a type of seaweed and contains a lot of carbohydrates and proteins. In particular, it is favorably used because of its high content of glycine and alanine, which are amino acids that have sweetness and flavor, to give a umami taste. Since early days, artificial culture has been practiced.

In such laver, spores epigenetize around October and reproduce throughout winter and spring, so for aquaculture, installations for spore epiphysis are installed in the sea in autumn, harvested, and grown. Epiphysis is good, but in artificial aquaculture, mainly bamboo poles or nets made of synthetic fiber nets are used.

In addition, as a suitable place for aquaculture, it is installed in a bay where the waves are calm and the tides communicate well.

In order to fix the drainboard, piles are driven into the shore and the drainboard is fixed to the stake.

Since the stakes are coastal, they are manually driven into the mud on the boat and used.

However, in the above seaweed culture (including seaweed, kelp, abalone, etc.), the water temperature rises due to global warming, and even if seaweed is grown on the coast, the amount of seaweed is dropping by about 30% compared to the past.

Also, seaweed can no longer be grown on the coast due to marine debris.

Because of this problem, some fishermen drive the stakes by striking them with a heavy pipe or the like above the water surface so that the stakes are driven into the bottom of the sea at a depth of at least 30 meters.

However, there is no way to check whether the pile is being driven or not, and even if it is, it is inefficient.

Fishermen who have seen the pile driving work do not trust the work method and are avoiding the work method.

The present inventor provided Korean Patent Registration No. 10-2111790 as an amount to solve the problems of the prior art, but a problem occurred.

Problem, when the crane 60 installed in the ship (not shown) is installed and the wire is released from the winder (not shown) installed in the crane, the hammer device connected to the wire goes down under the water and then the pile being operated by the hydraulic device (100) has to dig vertically down to the bottom of the deep sea, but if the wire is loosened, the hammer device 20 does not maintain verticality and tilts so that the pile driving operation cannot be performed or workability is inefficient.

In order to solve the above conventional problems, the present invention is to provide a vertical holding device (1) for holding the hydraulic hammer device vertically.

Looking at the configuration according to the attached drawings,

Both slide rails (4, 4a) vertically directed in both directions of a heavy object (3) that have a horizontal width and are erected vertically;

both slide members (5.5a) positioned or connected to elevate and descend on the both slide rails (4.4a);

It is connected to both the slide members (5.5a) by both hinge shafts (6, 6a), respectively.

a horizontal member 10 rotating in both directions with the hinge shafts 6 and 6a as a central axis;

In both directions (a) of the horizontal member (10) corresponding to both directions of the center corresponding to between the hinge shaft (6) and the hinge shaft (6a) in both directions of the horizontal member (10)

A state in which the pile 100 of the hydraulic pile device 20 is directed vertically is configured to connect the upper end of the hydraulic pile device 20 in both directions with a hinge 11 .

The following configuration is

It is configured so that both slide rails 4 and 4a do not incline or fall according to the waves of the waves by having weights 30 with a sense of weight on both sides of the lower end of the heavy object.

If the weight 30 is provided in this way, the workability is easy because it does not fall over by the wave.

The weight 30 is formed in plurality to selectively adjust the number of weights 30 according to the strength of the wave wavelength corresponding to the wave.

As described above, the present invention can drive a pile into the ground while maintaining the pile vertically by providing the vertical holding device 1 for maintaining the hydraulic hammer device vertically.

The above-mentioned effects are further revealed in the specific content.

1 is a perspective view of a conventional deep-sea pile driving hydraulic hammer device.
Figure 2 is an enlarged view of the lower part of Figure 1.
Figure 3 is a perspective view seen from the bottom of Figure 1.
4 is a conventional embodiment.
5 is a perspective view of another conventional embodiment;
6 is a vertical holding device of the deep sea pile driving hydraulic hammer device of the present invention.
A perspective view of a conventional hydraulic hammer device installed.
Fig. 7 is an enlarged view of the upper part of Fig. 6;
Fig. 8 is a plan view as viewed from the state of Fig. 6;
9 and 10 are explanatory views of the present invention.

First, looking at the conventional configuration with reference to the accompanying drawings, (Registration No. 10-2111790 is cited)

A body 10 having a length vertically and a width horizontally and

A hammer 20 is supported on the main body 10 , and a hammer striking unit 21 is positioned at the lower end of the hammer device 20 , and the hammer striking unit 21 clamps the stake 100 at the clamping portion 31 . or the clamp device 30 for releasing the clamp is fixed,

The body 10 has a water resistance plate 40 inserted horizontally and vertically in a plane, and includes a configuration to form a wire connection part 50 to which a wire descended from the crane 60 is connected.

The water resistance plate 40 is formed on the upper side of the body 10 so that the center of gravity of the body 10 faces downward.

The clamp device 30 is configured such that the clamp device 30 is detachably connected to the hammer striking unit 21 so that the clamp device 30 can be replaced according to the size of the pile 200 .

A wall 41 facing upward is formed on the edge of the water resistance plate 40 to further receive water resistance. This is the technical content invented by the present application.

An example of the conventional configuration will be described as follows.

After connecting a crane for winding a wire or releasing it from a winder (not shown) to a vessel (not shown), the pile 100 is vertically clamped to the clamp part 31, and then the wire (A) is started to be unwound from the winder. When the body 10 together with the pile 100 goes down under the water.

In the process, when the lower end of the pile 100 reaches the ground, the wire (A) is loosened. At this time, the loosened wire (A) is rewound and tightened, and then hydraulic pressure is supplied to the hammer device 20 to cause the hammer striking unit 21 to strike the pile 100 , the pile 100 digs into the ground. In the course of that work, the wire begins to unwind.

If the work continues in this way, the pile will dig underground.

After that, the operator stops the pile driving in consideration of the wire loosening condition.

The clamp device 30 is operated hydraulically to release the clamp from the pile 100 .

Then, the body 10 is returned to the original position above the water surface to proceed with the next pile driving operation.

To explain the water resistance plate 40 further, the water resistance plate 40 is formed on the body 10 to raise the body 10 when hitting the pile so that the water resistance plate 40 receives the resistance of water. It is configured to prevent the body from rising.

The prior art has a problem in that the pile 200 digs deep into the ground.

As described above, the main body 10 is tilted instead of maintained vertically so that the pile is tilted and digs into the ground.

In order to solve the above conventional problems, it is configured as follows.

Next, looking at the configuration of the present invention is as follows.

Both slide rails (4, 4a) which are horizontally wide and vertically directed in both directions of the heavy object (3) erected when erected vertically;

both slide members (5.5a) positioned or connected to elevate and descend on the both slide rails (4.4a);

It is connected to both the slide members (5.5a) by both hinge shafts (6, 6a), respectively.

a horizontal member 10 rotating in both directions with the hinge shafts 6 and 6a as a central axis;

In both directions (a) of the horizontal member (10) corresponding to both directions of the center corresponding to between the hinge shaft (6) and the hinge shaft (6a) in both directions of the horizontal member (10)

A state in which the pile 100 of the hydraulic pile device 20 is directed vertically is configured to connect the upper end of the hydraulic pile device 20 in both directions with a hinge 11 .

Consider the following configuration.

It is configured so that both slide rails 4 and 4a do not incline or fall according to the waves of the waves by having weights 30 with a sense of weight on both sides of the lower end of the heavy object.

If the weight 30 is provided in this way, the workability is easy because it does not fall over by the wave.

The weight 30 is formed in plurality to selectively adjust the number of weights 30 according to the strength of the wave wavelength corresponding to the wave.

If a plurality of weights 30 are formed in this way, for example, when the waves are calm, one weight is mounted among the plurality of weights.

Due to this, there is no need to unnecessarily mount the weight 30 . When the waves are calm, even if there is only one weight among the plurality of weights 30, both slide rails 4 and 4a do not fall over in the water.

An example of the configuration is as follows.

One side of the wire 101 is connected to the top of the deep sea pile driving hydraulic hammer device 20, and the other side of the wire is wound on a winder (not shown) of a crane (not shown).

When the wire is wound in this state, the horizontal member 10 is raised and lowered to the upper end of both slide rails 4 and 4a together with the hydraulic hammer device 20 on both slide rails 4 and 4a perpendicular to both directions of the heavy object. After winding the wire more, the weight (3) is lifted.

After that, unwind the wire from the winder and send the heavy object (3) equipped with the hydraulic hammer device (20) down to the bottom of the sea when the bottom of the heavy object (3) reaches the bottom of the sea.

For example, when the floor (ground) surface is the inclined surface 110 or is uneven, both slide rails 4 and 4a facing vertically are seated on the floor in an inclined state.

Even when seated at an angle like this, the hydraulic hammer device 20 is in a vertically erected state, and the reason is as follows.

9, for example, the lower end of one slide rail 4 among both slide rails 4 and 4a is located on the upper side 110a of the inclined surface 110, and the lower end of the other slide rail 4a is located on the inclined surface ( 110) When located on the lower side (110b),

As seen from the drawings, both hinge shafts 6 and 6a are in a state where one hinge shaft 6 is located on the upper side and the other hinge shaft 6a is located on the lower side along the inclined surface.

Therefore, when the horizontal member 10 is inclined, the horizontal member 10 connected to the upper end of the hydraulic hammer device 20 and the hinge 11 has the hinge 11 as the central axis, and the horizontal member 10 is It is tilted while rotating by a predetermined angle. At this time, the slide rails 4 and 4a are also inclined together.

In this process, the hydraulic hammer device 20 with a sense of weight is maintained vertically.

Hereinafter, the case shown in FIG. 5 will be described.

In the inclined surface of FIG. 10, the ground (seawater bottom) is an inclined surface in the same manner as in FIG. 9 .

For example, among the two slide rails 4 and 4a, one slide rail 4 is in the front as seen in the drawing, and the other slide rail 4a is in the rear.

In this case, referring to FIG. 10, both hinge shafts 6 and 6a are positioned in front and behind the center of the same inclined plane.

Accordingly, both the slide rails 4 and 4a are rotated and inclined by a predetermined angle with the hinge shafts 6 and 6a as central axes.

At this time, the hydraulic hammer device 20 with a sense of weight maintains the vertical and the horizontal member 10 maintains the horizontal.

3: heavy
4,4a: slide rail
5,5a: slide member
6,6a: hinge shaft
10: horizontal member
11: Hinge
20: hydraulic pile device
30: weight
100: pile

Claims (2)

Both slide rails (4, 4a) which are horizontally wide and vertically directed in both directions of the heavy object (3) erected when erected vertically;
both slide members (5, 5a) positioned or connected to elevate and descend on the both slide rails (4, 4a);

It is connected to both the slide members 5 and 5a by both hinge shafts 6 and 6a, respectively.
a horizontal member 10 rotating in both directions with the hinge shafts 6 and 6a as a central axis;

In both directions (a) of the horizontal member (10) corresponding to both directions of the center corresponding to between the hinge shaft (6) and the hinge shaft (6a) in both directions of the horizontal member (10)
Deep-sea pile driving hydraulic hammer device, characterized in that it includes a configuration that connects the upper end of the hydraulic pile device 20 in both directions with a hinge 11 in a state in which the pile 100 of the hydraulic pile device 20 is directed vertically vertical holding device. Deep-sea pile driving hydraulic hammer device, characterized in that it has weights 30 with a sense of weight on both sides of the lower end of the heavy object 3 so that both slide rails 4 and 4a do not tilt or fall according to the waves of the waves. of vertical holding device.

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