KR100519547B1 - A caisson structure - Google Patents

Abstract

Both wing pillars 112 and sofa pillars 110b of the sofa post 110a in the caisson sofa room 160 formed by removing a part of the front wall in consideration of the difference between tides and the depth of the blue height. The wing pillars 112 have a constant distance in the horizontal direction, and the sofa pillars 110a and the sofa pillars 110b are continuously arranged horizontally to easily absorb the blue energy invading from the front, and the sofa pillars in the vertical direction ( The sofa pillars 110a and the sofa pillars 110b are continuously horizontally arranged so that the ends of the one wing pillars 112a of the sofa pillars 110a serving to the ends of the one wing pillars 112 of 110b are slightly overlapped. By installing a Y-shaped sofa pillar characterized in that to block the reflected wave of the wave energy incident to the sofa room 160 to reduce the wave pressure in the process of injecting the wave energy invaded from the outside sea into the sofa room, sofa room 160 By sofa wall (161) When the reflected reflection wave is blocked by the reflection wave blocking walls 113 of the sofa pillars 110a and b, the wave energy incident on the sofa room 160 is converted into seawater exchange energy, and the seawater outlet 165 connected to the seawater induction hole 164 is provided. It relates to the sofa structure and seawater exchange structure of the breakwater and the quay caisson for seawater exchange through.

Description

A caisson structure

The harbor is the ship's entrance, the person's win. Unloading, unloading of cargo. It means that facilities for storage and treatment are provided, and in order to perform this function smoothly, it is necessary to block the blue energy invading from the open sea to secure the calm water in the harbor. To this end, breakwater facilities, cargo handling and people win. The ship's berth is required for unloading.

The breakwater is a sloped breakwater in which a sandstone is built on the sea floor and the sloped surface of the sandstone is covered with a covering stone or other sofa block, and an upright type that forms a sandstone mound on the bottom and an upright caisson is installed on the top surface. Hybrid breakwaters mixed with formulas;

Since the quay wall used as the ship's berthing facility should be planned as an upright, the block quay wall formed by stacking blocks and the caisson quay wall formed using caisson are typical.

Existing port facilities, such as existing, are the mainstream of the basic and economical facilities that follow the logistics and transportation of people.

However, due to the rapid development of logistics and human transportation systems in accordance with the development of the industry, the port facilities are also accompanied by rapid changes, and the development of ports suitable for modern industrial systems is essential. While maintaining the quietness of the harbor, clean seawater is exchanged with seawater from the inland sea to prevent pollution of the harbor, reducing the reflected wave of blue energy invading the sea and allowing small vessels to sail safely. It was necessary to develop breakwaters and quay caissons to significantly reduce the amount of waves entering the harbor.

The caisson for the breakwater is a perforated caisson breakwater, which is one of the special forms as shown in FIG. There is a caisson structured to be lifted. The merit of such a hole caisson is that the cross section of the upright type and the reflectance reduction effect of the perforated part have a smaller crest on the front of the breakwater than the case of the upright type. Therefore, it is possible to maintain the internal temperature of the harbor even if the tiandan height of the breakwater is lower than that of the upright breakwater. This is because wave energy is lost while the wave energy passes through the hole portion of the hole breakwater, and the energy is further reduced in the oil and gas chamber, thereby reducing the reflectance. When the rear wall is opened, the reflectance can be further reduced, and the hole breaker delays the action time of the wave, thereby reducing the maximum wave. Previous studies have shown that the perforation of a perforated breakwater is less than half of the perforated breakwater, and the positive pressure to lift the caisson on the bottom of the breakwater is also reduced.

However, in the case of the perforated caisson breakwater of FIG. Constraints are difficult to install in water bodies with large depths and high wave energy.

In the case of the perforated caisson of FIG. 1b, the front wall is installed as a perforated wall and the rear wall is installed as a non-pore to fill a heavy part in the space. The effect of maintaining the quietness in the port can be expected, but the effect of reducing the reflected wave is less because of the less oil chamber and the wall of the perforated wall than the perforated caisson. .

Referring to the caisson structure invented in order to improve the above disadvantages in detail based on the drawings as follows.

The unit caisson 100 drops the sandstone 20 on the top surface of the sea bottom 10 to form a sandstone foundation 30 and then flattens the top surface horizontally to form a center top surface of the foundation sandstone 30. The purpose can be achieved by providing the unit caisson 100 in the.

The unit caisson 100 according to the present invention has a shape of a rectangular parallelepiped whose body is open at the top. And the structure is one feature that the front wall 120 is not installed from the upper portion of the predetermined point from the lower plate 170.

In general, the front wall 120 is removed in consideration of the difference between tides from the average low tide water surface to the average high water surface and the height and depth of the blue water invading the entire sea surface.

A seawater induction wall having a sofa pillar support jaw 121 installed at an upper portion of the front wall 120 and a sofa pillar support jaw 121 having the same height as the front wall 120 at a rear side of the inland sea of the front wall 120. 162 is installed and the sofa wall 161 is placed at the same height as the side walls 130, the rear wall 140, and the partition wall 150 with a predetermined distance behind the sea side of the seawater induction wall 162. .

A space portion 171 is formed between the front wall 120 and the seawater induction wall 162, and the seawater induction hole 164 is formed between the seawater induction wall 162 and the sofa wall 161, and the seawater induction partition 163. Is formed together.

Here, the upper surface of the front wall 120 and the seawater induction wall 162 and the upper space of the sofa wall 161 at the same position become the sofa room 160, and the same position as the upper surface of the seawater induction wall 162. The space between the seawater induction wall 162 and the sofa wall 161 becomes the seawater induction hole 164 from the sofa wall 161 to the upper surface of the lower plate 170.

 Seawater outlet 165 is connected to the seawater induction hole 164 through the rear wall 140 is installed on the upper surface of the lower plate 170, in the case of the caisson for the quay wall seawater outlet 165 is an external sea side front wall ( 120 is connected to the seawater induction hole 164 through the lower portion is installed.

The Y-shaped sofa pillar 110 is installed on the top surface of the sofa pillar support jaw 121 installed on the front wall 120 and the seawater induction wall 162, and the sofa pillars 110a and b are the present invention. In another aspect, the front pillar 111 is formed in the form of a plate vertically, vertically and both wing pillars 112 on the inboard sea side rear of the front pillar 111 spread the wings in the inshore direction It is also formed vertically up and down.

Y-shaped sofa pillars (110a, b) are the front and rear positions of both wing pillars 112 are staggered, respectively, the left and right positions are arranged to partially overlap the cover plate 114 and the front pillar 111 and both It is produced by connecting the lower portion of the wing pillar (112). Here, the front pillar 111 is shown in order to arrange the front in the same position in the transverse direction in consideration of the arrangement aesthetic, but mention that the front and rear length of the front pillar 111 can be adjusted to suit the purpose. and. In FIG. 2, three sofa pillars 110a and b are connected to the cover plate 114 to form a set, and thus, the sofa pillars 110a and b may be mounted on the sofa pillar support jaw 121. One set of mounting units can be made, both wing pillars 112 can also be produced in more than one.

After filling the heavy object 172 in the space portion 171 of the unit caisson 100 configured as described above and the sofa pillars (110a, b) mounted on the upper surface of the sofa pillar support jaw 121, the sofa pillars (110a, b) By placing the damascene concrete 180 on the upper portion of the unit caisson 100 to fix the breakwater by the unit caisson according to the present invention is constructed.

Referring to the sofa structure and the seawater exchange structure of the unit caisson 100 according to the present invention.

As mentioned above, as shown in the plan view of the unit caisson 100 of FIG. 3, the front pillars 111 of the sofa pillars 110a and the sofa pillars 110b have their front sides at the same positions in the transverse direction. Before and after adjusting the length of the front column 111 to align the front of the wing pillars 112 are arranged with different positions, respectively.

That is, the two wing pillars 112 of the sofa pillar 110a and the wing pillars 112 of the sofa pillar 110b are arranged at a predetermined distance in the horizontal direction to easily absorb the blue energy invading from the front, and vertically. The end of the sofa pillar (110a) one side of the wing pillar 112, which is treated to the end of the sofa wing (110a) of the sofa pillar (110b) in the direction continuously arranged horizontally to form a slight overlap to the sofa room 160 It completely blocks the reflected wave of incident wave energy.

The blue energy invading from the front of the sofa pillars 110a and b arranged as described above is incident to the sofa room 160 of the unit caisson 100 as shown in FIG. 4.

The blue energy is separated by the front pillars 111, respectively, so that the wall surfaces of the two wing pillars 112 of the sofa pillars 110b substantially reduce the wave power without substantially reflecting the blue energy, and the two blades of the sofa pillars 110a. Pillar 112 also reduces the second order with little reflection of the wave energy.

The width of the front portion between the front pillar 111 of the sofa pillar (110a) and the front pillar (111) of the sofa pillar (110b), the sofa pillar to be treated with the end of one wing pillar of the sofa pillar (110b) than W as shown in FIG. Since the width between one side of the front pillar 111 of 110a, W 'is narrow and W1' is also narrow compared to the width of W1, the jet effect is induced at two points of W 'and W1'. It causes a reduction effect of wave energy.

The two points, W 'and W1', are also the points where the wave energy of the wave energy increases.

As described above, the wave energy passing through two points of W 'and W1' is separated into both sides by the sofa wall 161, and most of the separated wave energy is reflected wave blocking wall 113 of the sofa post 110a. ) And a part of the sofa is couched by the reflection wave blocking wall 113 of the sofa pillar 110b. Since the blue wave proceeds in the form of a straight line, the pressure is applied at two points, W 'and W1', due to the wave pressure of the overlapping wing pillars 112 and the wave energy invading from the front. The wave energy incident on the 160 does not flow out of the unit caisson 100 again.

Referring to the cross-sectional view of FIG. 5, the wave energy incident to the sofa room 160 is reflected by the sofa wall 161 in the direction of the external sea, but is absorbed into the wave guide hole 164 by the reflection wave blocking wall 113 and is absorbed. The wave energy is to flow into the inland sea through the seawater outlet (165).

It is possible to efficiently absorb the incident wave energy through the seawater induction hole 164 and the seawater outlet 165 formed in the unit caisson 100, the wave energy incident to the sofa room 160 seawater of the external sea and seawater of the inland sea This is because the energy is changed into exchange energy to exchange. If the seawater induction hole 164 and the seawater outlet 165 are not formed inside the unit caisson 100, the wave energy incident to the sofa room 160 of the unit caisson 100 may not be efficiently couched.

For this reason, the seawater induction hole 164 and the seawater outlet 165 may also be a feature and an essential component of the unit caisson 100 according to the present invention.

In addition, since the positive pressure acts differently according to the cross-sectional sizes of the seawater induction hole 164 and the seawater outlet 165 in the case of the breakwater, when the opening 190 is additionally formed in the concrete concrete 180, the positive pressure is increased as shown in FIG. 6. I can alleviate it.

In addition, the unit caisson 100 according to the present invention can be used not only for the use of the breakwater described above, but also forms the seawater outlet 165 on the front wall 120 in the outer sea direction as shown in FIG. If the backfilling seat is filled with the insect repellent material 181 and the mooring column 182, the reflected wave of the blue energy incident on the inner wall can be completely blocked and used as a caisson for the inner wall.

As described above, the unit caisson 100 according to the present invention can be used for a breakwater as well as a quay wall. When the breakwater is formed using the unit caisson 100 according to the present invention, the following effects are obtained.

First, the perforated caisson reflects the blue energy of the external sea by the porosity of the front wall is not completely absorbed from the front wall, but the unit caisson 100 according to the present invention completely removes a part of the front wall. Since the sofa posts 110a and b are installed, the reflected wave is not generated because the wave energy is completely incident.

Second, the wave energy invading the open sea generates positive pressure to lift the main unit caisson 100 to the upper part, and the point at which the positive pressure occurs is the front wall and the sofa wall 161 of the unit caisson 100. Since it is divided into two generations, it is structurally safe and economical even if the system weight is made smaller than the perforated caisson or seawater distribution cai due to the time difference.

Third, the wave energy incident on the sofa room 160 of the unit caisson 100 is not reflected to the outside of the unit caisson 100 by the reflection wave blocking wall 113, but is absorbed by the seawater induction hole 164 and thus the seawater outlet ( 165), it can flow into the inland sea to maintain the calmness of the inland sea.

Fourth, since the wave energy incident on the sofa room 160 of the unit caisson 100 is converted into seawater exchange energy using the reflection wave blocking wall 113 and the seawater induction hole 164, the seawater of the open sea and the seawater of the inland sea are exchanged. You can increase the rate.

Fifth, since the wave energy invading in the open sea is completely incident into the sofa room 160, the amount of waves exceeding the upper concrete 180 of the breakwater can be significantly reduced.

1A and B are lateral sectional views showing a sofa and seawater distribution structure of a conventional caisson;

Figure 2 is a partially exploded perspective view of the caisson partially cut according to the present invention.

3 is a plan view of a caisson according to the present invention.

Figure 4 is a plan view showing the flow of the wave incident to the caisson and the sofa process according to the present invention

Fig. 5 is a lateral cross-sectional view showing a blue sofa and seawater exchange structure entering the caisson according to the present invention.

Figure 6 is a cross-sectional view showing another embodiment of the caisson for breakwater according to the present invention

Fig. 7 is a lateral sectional view showing another blue flow structure of caisson according to the present invention.

<Explanation of Signs of Major Parts of Drawings>

10. The sea floor

30. Basalt Foundation 100. Unit caisson

110 (a, b). Sofa pillar 111.Front pillar

112. Two-winged Pillar 113. Reflective Barrier

114. Cover plate 120. Front wall

121. Sofa pillar support 130. Both side walls

140. Rear wall 150. Bulkhead

160. Sofa Room 161. Sofa Wall

162. Guided Seawater Walls 163. Guided Seawater Bulkheads

164. Seawater induction hole 165. Seawater outlet

170. Bottom plate 171. Space section

172.Heavyweight 180.Place Concrete

181. Insect repellent 182. Mooring line

190. Opening opening 200. Perforated wall

300. Runner Room

Claims (6)

The unit caisson 100 drops the sandstone 20 on the top surface of the sea bottom 10 to form a sandstone foundation 30 and then flattens the top surface horizontally to form a center top surface of the foundation sandstone 30. The unit caisson 100 is installed in the unit, but the front wall 120 of the unit caisson 100 is partially removed, and a sofa pillar support jaw 121 is provided on the upper portion of the front plate 120 on the upper surface of the lower plate 170. ), The seawater guide wall 162 having a sofa post support 121 having the same height as the front wall 120 behind the inland sea side of the front wall 120, and the seawater guide wall 162. When the sofa wall 161 is placed at the same height along the side walls 130, the rear wall 140, and the partition wall 150 at a predetermined distance from the rear, the front wall 120 and the seawater induction wall 162 Between the space portion 171, the sofa room 160 is formed in the space from the top of the front wall 120 to the sofa wall 161 at the same position as the top of the front wall 120, sea water A seawater induction hole 164 is constructed together with the seawater induction partition 163 in the space between the induction wall 162 and the sofa wall 161, and the seawater outlet 165 passes through the rear wall 140 on the upper surface of the lower plate 170. ) Is installed to connect to the seawater induction hole 164, Y-shaped sofa pillar 110 on the upper surface of the sofa pillar support jaw 121 installed on the front wall 120 and the seawater guide wall 162. By installing, by filling the weight 172 in each space portion 171, by placing the upper concrete 180 on the unit caisson 100 so that the sofa pillar 110 and the upper concrete 180 can be integrated. Caisson structure structured. The method of claim 1 Sofa pillars (110a, b) is the front pillar 111 is formed vertically up and down in the form of a plate, both wing pillars 112 on the rear of the front pillar 111 spread the wings in the direction of the sofa wall (161) The caisson structure having a Y-shaped assembled sofa pillar 110, which is also formed vertically up and down and the lower portion of the sofa pillars (110a, b) is connected to the cover plate (114).       The method of claim 1      The two wing pillars 112a of the sofa pillar 110a and the two wing pillars 112 of the sofa pillar 110b are horizontally arranged horizontally with the sofa pillar 110a and the sofa pillar 110b continuously spaced apart at a horizontal distance. The sofa pillars 110a and the sofa pillars 110b are formed so that the ends of the wing pillars 112a of the sofa pillars 110a, which are treated at the ends of the sofa pillars 110b of the sofa pillars 110b in the vertical direction, overlap with each other. The caisson structure characterized by being horizontally arrange | positioned to this sofa room 160 continuously. The method of claim 1 The caisson structure, characterized in that further forming an opening (190) in the upper concrete 180.  The unit caisson 100 drops the sandstone 20 on the top surface of the sea bottom 10 to form a sandstone foundation 30 and then flattens the top surface horizontally to form a center top surface of the foundation sandstone 30. The unit caisson 100 is installed in the unit, but the front wall 120 of the unit caisson 100 is partially removed, and a sofa pillar support jaw 121 is provided on the upper portion of the front plate 120 on the upper surface of the lower plate 170. ), The seawater guide wall 162 having a sofa post support 121 having the same height as the front wall 120 behind the inland sea side of the front wall 120, and the seawater guide wall 162. When the sofa wall 161 is placed at the same height along the side walls 130, the rear wall 140, and the partition wall 150 at a predetermined distance from the rear, the front wall 120 and the seawater induction wall 162 Between the space portion 171, the sofa room 160 is formed in the space from the top of the front wall 120 to the sofa wall 161 at the same position as the top of the front wall 120, sea water A seawater induction hole 164 is constructed together with the seawater induction partition 163 in the space between the induction wall 162 and the sofa wall 161, and the seawater penetrates the front wall 120 in the outer sea direction on the upper surface of the lower plate 170. A plurality of outlets 165 are installed to be connected to the seawater induction hole 164, and the Y-shaped sofa pillars are formed on the upper surface of the sofa pillar support jaw 121 installed on the front wall 120 and the seawater induction wall 162. 110 is installed, each of the space portion 171 to fill the weight 172, the back wall filling the filling seat, the sofa pillar 110 and the concrete concrete 180 so that the unit caisson (100) can be integrated. The caisson structure which is constructed by pouring the damascene concrete 180 provided with the insect repellent 181 and the mooring column 182 on the top. delete