KR101529437B1 - Marine resort structure - Google Patents

Abstract

The present invention relates to a marine resort structure having marine resting facilities such as a hotel, marine sightseeing facilities such as an observation platform, and marine leisure facilities such as facilities for fishing or scuba diving. The marine resort structure includes a main tower installed on the sea; multiple sub towers radially arranged in the outer side of the main tower around the main tower; and multiple seawalls connecting the main and sub towers.

Description

Marine resort structure

The present invention relates to a marine resort structure, and more particularly, to a marine resort structure having a marine tourism facility such as a hotel, a rest facility such as a hotel, a gazebo, and a marine leisure facility such as a fishing boat or scuba diving.

Conventional maritime tourism is only a fractional transient sightseeing tour, such as natural coastal scenery on board a ship while admiring it. It is possible to stay for a certain period of time and enjoy a view of the surrounding scenery while fishing or scuba diving There was no other marine structure to enjoy leisure.

On the other hand, a lighthouse is installed at a designated place on the sea for safe operation of the ships. These lighthouses are constructed to illuminate the marine by installing light fixtures at certain positions of the lighthouse so that the position of the lighthouse can be easily identified at night. The lighthouse illuminates the land material, perspective and dangerous area Can be grasped.

In the case of harbor, a breakwater extends from one side of the coast to the sea side and a lighthouse is installed at the end of the breakwater. Generally, the seawater and the outer sea are separated from each other by a breakwater, and a plurality of sofas It is constructed in such a way that the blocks are laid.

However, since the seawater of the Inland Sea is separated from the outer sea, the seawater of the Inland Sea and the outer Sea are not communicated with each other, and the seawater of the Inland Sea is polluted and various kinds of dirt accumulate. There is a problem that the ecosystem of the ecosystem is destroyed. In addition, the seawater can not pass through the breakwater structure, and all the wave energy is reflected, so that a large force is applied to the breakwater structure, and the durability of the breakwater structure itself is inferior. As the surging wave energy and the reflected wave are combined, There are also problems that arise.

Recently, a breakwater has been constructed to allow the seawater of the sea and inland water to freely communicate with the breakwater through the breakwater. In this case, however, the end portion of the breakwater where the lighthouse is installed is constructed by a concrete block filled with the inside, which adversely affects the flow of natural seawater In fact.

In addition, the conventional lighthouse is installed on the coast or the island and serves only to illuminate at night, and no additional facilities for marine tourism or marine leisure are installed.

KR 10-0307218 B1 (Aug. 20, 2001) Enrollment) KR 20-0444161 Y1 (2009.04.08 Enrollment) KR 10-1379040 B1 (March 23, 2014 Enrollment)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a marine resort structure capable of enjoying accommodation facilities, marine tourism, and marine leisure facilities.

Another object of the present invention is to provide a marine resort structure that naturally flows the sea water and does not adversely affect the marine ecosystem.

Another object of the present invention is to create value added by tourism commercialization of the lighthouse installation area and to provide comfortable rest space and space for marine leisure together with the lighthouse unique function.

SUMMARY OF THE INVENTION The object of the present invention is to provide a main tower, An auxiliary tower disposed radially outward of the main tower around the main tower; And a plurality of breakwaters connecting the main tower and the auxiliary tower to each other.

According to a preferred aspect of the present invention, a lodging facility is installed in the main tower, and a resort or a leisure facility may be installed in the auxiliary tower.

According to another preferred aspect of the present invention, a park, a walkway, a fishing boat, or a ship berthing facility may be installed on one side of the breakwater.

According to another preferred aspect of the present invention, the main tower and the auxiliary tower may be multi-layered structures having a plurality of unit layers.

According to another preferred aspect of the present invention, the main lighthouse is installed on the uppermost layer of the main tower, and the auxiliary lighthouse is installed on the uppermost layer of at least one of the plurality of auxiliary towers.

According to another preferred aspect of the present invention, the main tower comprises: a support layer formed of at least one unit layer and immersed below the sea surface; and a facility layer formed as at least one unit layer above the support layer, .
According to another preferred aspect of the present invention, at least one room formed in the facility layer may be provided with a slide extending in the sea level direction.

According to another preferred aspect of the present invention, the unit layer constituting the support layer includes a support plate and a plurality of support pillars supporting the bottom surface of the support plate, wherein the plurality of support pillars are mutually spaced from each other Can be spaced apart.

According to another preferred aspect of the present invention, the support plate may be formed by coupling a plurality of unit plates on the same plane.

According to another preferred aspect of the present invention, the support plate may include a support portion formed at the center and a flange portion extending outwardly of the support portion along the periphery of the support portion.

According to another preferred aspect of the present invention, a plurality of support column insertion grooves into which one end of the support column is inserted may be formed on one surface of the support plate.

According to another preferred feature of the present invention, the main tower further includes a first base installed on the sea bed, and the lowest-level support plate of the support layer may be seated above the first base.

According to another preferred feature of the present invention, the first base can be seated on a plurality of supports installed on the seabed.

According to another preferred aspect of the present invention, the auxiliary tower comprises: a reinforcing layer formed of at least one unit layer and immersed below the sea surface; and an outlook layer formed of at least one unit layer on the upper side of the reinforcing layer, .

According to another preferred aspect of the present invention, the unit layer constituting the reinforcing layer includes a reinforcing plate and a plurality of reinforcing pillars for supporting the bottom surface of the reinforcing plate, wherein the plurality of reinforcing pillars are mutually spaced from each other Can be spaced apart.

According to another preferred aspect of the present invention, the reinforcing plate may include a reinforcing portion formed at the center, and an enlarged portion formed to extend outside the reinforcing portion along the periphery of the reinforcing portion.

According to another preferred feature of the present invention, an underwater image acquisition device for displaying an object in water in real time can be provided in any one of the view layers.

According to another preferred feature of the present invention, a detection sensor for detecting the approach of the ship and an alarm for emitting a warning sound when the ship is approaching can be installed on one side of the main lighthouse or the auxiliary lighthouse.

According to another preferred aspect of the present invention, a plurality of measurement devices installed at a plurality of locations in the main tower or the auxiliary tower, the plurality of measurement devices measuring at least one of subsidence, inclination, wave pressure, and wave height for each site; A communication device for performing short-distance communication with the measurement device by wire or wireless; A storage for storing measured values received via the communication device; And a management device for determining a failure state of the main tower or the auxiliary tower based on the measured value, wherein the management device is configured to determine at least one of a settlement change amount, an inclination change amount, a wave pressure, A reference range storage unit for storing the measured values currently received through the communication device in the reference range storage unit, A reference range comparison unit for comparing the measured value with a stored reference range, and a reference range comparison unit for comparing the measured value received through the communication unit with a reference range stored in the reference range storage unit, And a failure state determining unit for determining the failure state.

According to the present invention, it is possible to provide a resort facility for enjoying accommodation, maritime sightseeing, and marine leisure, in addition to the lighthouse's role for guiding the safe operation of the ship.

In addition, according to the present invention, since the main tower, the lower part of the auxiliary tower, and the breakwater are formed so as to allow the flow of seawater, it is possible to prevent the ecosystem change due to algae change.

In addition, according to the sea resort structure according to the present invention, by adding a resort facility to the area where only the conventional lighthouse was installed, it is possible to generate profit by tourism merchandising.

In addition, according to the present invention, it is possible to measure a settlement, a slope, a wave pressure, a crest, and the like of an offshore resort structure, determine a damage state thereof, and predict a maintenance time for maintenance according to the determined damage state .

In addition, according to the present invention, when a settlement, a slope, a wave pressure, a crest, etc. of a floating resort structure is suddenly changed by a natural disaster such as a typhoon, an earthquake or a tsunami, To the manager so that the manager can take prompt response for maintenance.

1 is a perspective view of a marine resort structure according to an embodiment of the present invention;
2 is a front view of a marine resort structure according to an embodiment of the present invention;
3 is a plan view of a marine resort structure in accordance with an embodiment of the present invention.
4 is a cross-sectional view of a main tower according to an embodiment of the present invention;
5 is a cross-sectional view of an auxiliary tower in accordance with an embodiment of the present invention.
FIG. 6 is a schematic diagram of a maintenance and measurement system for a marine resort structure according to an embodiment of the present invention; FIG.
FIG. 7 is a schematic view showing an example of the management apparatus of FIG. 6;
8 is a view showing an example of a breakage state judgment reference range;
Fig. 9 is a schematic view showing another example of the management apparatus of Fig. 8; Fig.
10 is a schematic view showing still another example of the management apparatus of Fig.
11 is a schematic diagram of an automatic management apparatus for a marine lighthouse structure according to an embodiment of the present invention.
12 is a schematic view of an automatic management apparatus for a marine lighthouse structure according to another embodiment of the present invention.
13 is a schematic view of an automatic management apparatus for a marine lighthouse structure according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the embodiments described below are only for explanation of the embodiments of the present invention so that those skilled in the art can easily carry out the invention, It does not mean anything. In describing various embodiments of the present invention, the same reference numerals are used for components having the same technical characteristics.

Example

FIG. 1 is a perspective view of a marine resort structure according to an embodiment of the present invention. FIG. 2 is a front view of a marine resort structure according to an embodiment of the present invention. Fig.

1 to 3, the marine resort structure 100 according to an embodiment of the present invention is installed at sea from the land. At this time, a breakwater (not shown) extending from the coast may be connected to one side of the sea resort structure 100. That is, the marine resort structure 100 according to an embodiment of the present invention may be installed independently on the sea, such as an island, or on one side of a breakwater extending from the coast.

When the marine resort structure 100 according to an embodiment of the present invention is installed solely on the sea, the user can access the marine resort structure 100 by using a transportation means such as a ship or a helicopter. When installed on one side of a breakwater, it can be accessed by a vehicle or a pedestrian through a breakwater in addition to transportation means such as a ship or a helicopter.

In addition, since the lighthouse 10 is installed on the uppermost layer of the sea resort structure 100 according to the embodiment of the present invention, the lighthouse 10 can be installed in an area requiring the lighthouse 10 for safe navigation of the ship. Of course, the marine resort structure 100 may be installed in an area that does not require the lighthouse 10. In this case, the lighthouse 10 installed on the uppermost floor serves as a lighting for illuminating the surrounding scenery such as the night sea rather than the navigation guide of the ship .

The marine resort structure 100 according to an embodiment of the present invention includes a main tower 200 and a plurality of auxiliary towers 300 radially formed outside the main tower 200. It is preferable that the width of the main tower 200 is wider than the width of the auxiliary tower 300. This is mainly because the main tower 200 is made up of recreational facilities capable of accommodating the guests such as a marine hotel, This is because it is a leisure facility where you can enjoy marine tourism or marine leisure. Guests can enjoy maritime sightseeing or marine leisure at each of the auxiliary towers 300 during the day, and return to the accommodations at the main tower 200 at night to relax. Of course, it is also possible to use only the leisure facility of the auxiliary tower 300 without using the accommodation of the main tower 200.

The main tower 200 and the auxiliary tower 300 are partitioned into a plurality of layers, some of which are submerged below sea level and some of which are exposed above sea level. It is preferable that the submerged layer below the sea surface is formed in a structure in which the sea water can flow naturally so as not to affect the ocean current.

The main tower 200 and the auxiliary tower 300 are connected to each other by a breakwater 400. Since the breakwater 400 serves to lower the energy of the waves approaching from the outer sea, the sea between the breakwater 400 and the breakwater 400 adjacent to each other can be used for swimming, scuba diving, jet skiing, Leisure can be enjoyed comfortably.

A ship berthing facility (not shown) may be installed at one side of the breakwater 400. An upper side of the breakwater 400 may be used as a road, a promenade, a park, or a lesser facility such as a fishing line.

It should be noted that the present invention is not limited by the shape and lamination structure of the breakwater 400, and thus, all known breakwater structures can be applied. Preferably, the breakwater 400 having a structure in which the wave energy of a wave approaching from the outer sea is reduced while the circulation of the sea water is free is applied. The main tower 200, the auxiliary tower 300, and the breakwater 400 may be basically constructed of reinforced concrete for durability. If necessary, the main tower 200, the auxiliary tower 300, May be constructed with a steel structure.

4 is a cross-sectional view of a main tower according to an embodiment of the present invention.

According to an embodiment of the present invention, as shown in FIG. 4, a plurality of first supports 210 are vertically installed on the seabed. At this time, the specifications such as the number, the width, and the height of the first supports 210 can be variously selected as needed. In addition, the first support 210 may have a pile shape having various cross-sectional shapes such as a circular shape or a polygonal shape.

The first base 220 is installed on the first support 210. The first base 220 together with the first support 210 supports the facility layer 201 and the support layer 202 to be described later and is preferably stably mounted on the sea floor.

At this time, the first base 220 and the first support 210 may be integrally formed. That is, the first support 210 may protrude downward from the bottom of the first base 220. It is also possible that the first base 220 and the first support 210 are individually manufactured according to need. In this case, the upper end of the first support 210 may be formed in the bottom of the first base 220, (Not shown) so as to prevent the first base 220 from flowing.

Alternatively, as another example of the present invention, the first base 220 may be supported by a quarry, and the first base 220 may be directly seated on the undersea surface without a separate first support 210.

The multi-layered structure is seated on top of the first base 220. The multi-layer structure includes a plurality of unit layers stacked, and the unit layer includes a plurality of support columns 240 supporting the support plate 230 and a lower portion of the support plate 230.

The dimensions such as the number of unit layers constituting the multi-layer structure, the width and thickness of the support plate 230, the height of the support column 240, and the like can be appropriately selected as needed. At this time, a plurality of unit layers constituting the upper part of the multi-layer structure are exposed on the sea surface, and constitute a facility layer 201 where accommodation facilities, rest facilities or tourism and leisure facilities are installed. In the lower part of the facility layer 201, a plurality of unit layers are submerged below the sea level and constitute a support layer 202 supporting the facility layer 201.

The support plate 230 may be of various shapes. Although the support plate 230 in the shape of a circular plate is shown in the drawing, it is needless to say that the support plate 230 may have various shapes such as an elliptical shape and a polygonal shape.

The support plate 230 according to an embodiment of the present invention includes a support portion 231 formed at the center and a flange portion 232 extending outwardly of the support portion 231 along the periphery of the support portion 231 . The supporting portion 231 is a portion where the plurality of supporting pillars 240 are supported and therefore the thickness of the supporting portion 231 is preferably thicker than the thickness of the flange portion 232 for reinforcing the rigidity. Supporting column insertion grooves 231a are formed in the upper and lower sides of the support portion 231 so that the lower ends and the upper ends of the support columns 240 are respectively inserted. If necessary, a plurality of support post insertion grooves may be formed in the flange portion 232 so as to be supported by the support posts 240. It is also possible that the support pillars 240 pass through the support plates 230 of each layer in order and extend in the height direction.

On the other hand, when the size of the support plate 230 is considerably large, it is difficult to manufacture, transport, and construct, so that it is preferable to divide the unit plate into a plurality of unit plates (not shown). For example, a plurality of unit plates in the form of a fan and an arc are manufactured and transported to the installation site, and then the unit plates are coupled on the support columns 240 in the circumferential direction and the radial direction on the same plane, . At this time, the size, shape, and number of the unit plates can be appropriately selected according to the size of the support plate 230, the manufacturing, transportation, and convenience of construction.

The support plate 230 of the lowest layer is seated on the first base 220 and the support portion 231 of the support plate 230 is inserted into the first receiving groove 221 provided on the upper side of the first base 220 . The first receiving groove 221 of the first base 220 may be formed to correspond to the supporting portion 231 of the supporting plate 230. The flange portion 232 of the support plate 230 is brought into close contact with the upper surface of the first base 220 along the periphery of the first receiving groove 221 so that the flow of the lowermost support plate 230 is prevented.

The support pillars 240 are inserted into the plurality of support column insertion grooves 231a formed on the upper surface of the support plate 230 and vertically installed. The support plate 230 is seated on the upper end of the supporting column 240. That is, the support plate 230 and the support columns 240 are alternately stacked to form a plurality of unit layers, and the upper surface of the support plate 230 constitutes the bottom surface of each unit layer.

The load is concentrated on the support portion 231 of the lowermost support plate 230 since the plurality of support pillars 240 are seated on the support portion 231 of the support plate 230. Therefore, it is preferable that the first support 210 supporting the first base 220 is also densely arranged in the region corresponding to the support 231 of the lowermost support plate 230.

A plurality of support columns 240, which are erected vertically together on one support plate 230 and support the support plate 230 on the upper support plate 230, are spaced apart from each other to form a gap therebetween, The seawater can be circulated through the gaps between the support pillars 240 of the support layer 202, which will be described later.

The plurality of support plates 230 exposed on the sea surface constitute the facility layer 201. A railway 250 is installed along the perimeter of each support plate 230 to prevent safety accidents, You can enjoy watching. A plurality of vertical bars 251 may be spaced apart from each other along an upper edge of the support plate 230 and each vertical bar 251 may be connected to a rail 250 by a rope 252 or a chain, Can be formed. As another example, a glass window or a wall may be installed along the periphery of one facility layer 201 to divide the inside and the outside of the facility, and accommodation facilities such as a room or rest facilities such as a restaurant or a cafe may be installed.

Here, in the case of the embodiment shown in the drawings, the unit layer constituting the facility layer 201 is configured to have the same structure as the support layer 202 described later. However, in the case of the facility layer 201, The gap between the support layer 202 and the support layer 202 can be widely arranged.

A lighthouse 10 may be installed at the center of the uppermost facility layer 201 and the uppermost support plate 230 on which the lighthouse 10 is installed may have the width of the flange portion 232 of the support plate 230 It can be formed relatively narrow.

On the other hand, a plurality of unit layers, which are located below the facility layer 201 and are locked below the sea level, constitute a support layer 202 for supporting the facility layer 201. Like the facility layer 201 described above, the support layer 230 and the plurality of support columns 240 supporting the support plate 230 are preferably formed by appropriately selecting the number of layers depending on the depth of the support layer 202 ) Constitute a unit layer. The plurality of support pillars 240 are spaced apart from each other with a predetermined gap therebetween, and the seawater is freely circulated through the clearance.

In the multi-layer structure including the support layer 202 and the facility layer 201, it is preferable that a passageway 260 communicating the upper layer and the lower layer is formed so that each layer can be moved up and down. As shown in the figure, a passageway 260 is vertically communicated at one side of the flange portion 232 of the support plate 230, and a ladder 261 is installed in each passageway 260 have. As another example, a passageway 260 may be formed around the central support column 240 and a spiral step (not shown) may be provided along the periphery thereof, or an elevator (not shown) may be installed. The user can freely use various accommodation facilities and rest facilities installed in the respective facility floors 201 while moving up and down through the passageway 260.

As another example of the present invention, a passageway (not shown) may be formed in a part or the whole of a room formed in the facility layer 201 so as to pass directly to the sea. For example, a slider extending in the direction of the sea surface may be installed on the window side of the room facing the sea, and the guest can quickly swim down to the sea surface in the slide to enjoy swimming.

The marine resort structure 100 according to an embodiment of the present invention can be installed solely on the sea. In this case, a mooring facility for berthing the ship can be installed in a part of the facility layer 201 of the main tower 200 have. As another example, it is also possible that the marine resort structure 100 is installed at the end of the breakwater 400 extending from land to sea, wherein the users can walk through the breakwater 400 or through the vehicle to the main tower 200, The user can enter the facility layer 201 of the facility.

5 is a cross-sectional view of an auxiliary tower according to an embodiment of the present invention.

A plurality of auxiliary towers 300 according to an embodiment of the present invention are formed radially outside the main tower 200 around the main tower 200. Each of the auxiliary towers 300 includes a main tower 200, And the breakwater 400. Hereinafter, the configuration of the auxiliary tower 300 will be described in detail with reference to FIG.

First, a plurality of second supports 310 are vertically installed on the seabed. At this time, the specifications such as the number, the width, and the height of the second supports 310 can be variously selected as needed. In addition, the second support platform 310 may be formed as a pile having various cross-sectional shapes such as a circular shape or a polygonal shape.

A second base 320 is installed on the second support 310. The second base 320 supports the view layer 301 and the reinforcing layer 302 together with the second support 310 and is preferably stably mounted on the sea floor.

At this time, the second base 320 and the second support 310 may be integrally formed. That is, the second support base 310 may protrude downward from the bottom surface of the second base 320. The second base 320 and the second support 310 may be separately manufactured as required. In this case, the upper end of the second support 310 may be formed in the bottom of the second base 320, (Not shown) so as to prevent the second base 320 from flowing.

As another example of the present invention, it is also possible that the second base 320 is supported by a sandstone and the second base 320 is directly seated on the seabed without a separate second support 310.

The multi-layer structure is seated on top of the second base 320. The unit layer includes a reinforcing plate 330 and a plurality of reinforcing pillars 340 for supporting a lower portion of the reinforcing plate 330.

The dimensions such as the number of unit layers constituting the multi-layer structure, the width and thickness of the reinforcing plate 330, the height of the reinforcing pillar 340, and the like can be appropriately selected as necessary. At this time, a plurality of unit layers constituting the upper part of the multi-layer structure are exposed on the sea surface, and form a view layer 301 in which rest facilities or tourism and leisure facilities are installed. In the lower part of the view layer 301, a plurality of unit layers are submerged below sea level, and form a reinforcing layer 302 supporting the view layer 301.

The reinforcing plate 330 may have various shapes. Although the reinforcing plate 330 having a circular plate shape is shown in the figure, it may be formed in various shapes such as elliptical or polygonal shapes as required.

The reinforcing plate 330 according to an embodiment of the present invention includes a reinforcing portion 331 formed at the center and an enlarged portion 332 extending to the outside of the reinforcing portion 331 along the periphery of the reinforcing portion 331, . The reinforcing portion 331 is a portion where the plurality of reinforcing pillars 340 are supported. Therefore, it is preferable that the thickness of the reinforcing portion 331 is thicker than the thickness of the extending portion 332 for reinforcing the rigidity. A reinforcing column insertion groove 331a is formed in the upper and lower sides of the reinforcing portion 331 so that the lower end and the upper end of the reinforcing column 340 are inserted, respectively. If necessary, a plurality of reinforcing column insertion grooves may be formed in the extending portion 332 to be supported by the reinforcing pillars 340. It is also possible that the reinforcing pillars 340 pass through the reinforcing plates 330 of the respective layers in order to be elongated in the height direction.

On the other hand, when the size of the reinforcing plate 330 is considerably large, it is difficult to manufacture, transport, and construct, so that it is preferable to divide the reinforcing plate 330 into a plurality of unit plates (not shown). For example, a plurality of fan-shaped and arcuate unit plates may be manufactured and transported to the installation site, and the unit plates may be sequentially mounted on the reinforcing pillars 340 along the circumferential and radial directions on the same plane to form the shape of the reinforcing plate 330 . At this time, the size, shape, and number of the unit plates can be appropriately selected according to the size of the reinforcing plate 330, manufacturing, transportation, and construction convenience.

The reinforcing plate 330 of the lowest layer is seated on the second base 320 and the reinforcing portion 331 of the reinforcing plate 330 is inserted into the second receiving groove 321 provided on the upper side of the second base 320, . At this time, the second receiving groove 321 of the second base 320 is preferably formed in a shape corresponding to the reinforcing portion 331 of the reinforcing plate 330. The extended portion 332 of the reinforcing plate 330 is brought into close contact with the upper surface of the second base 320 along the periphery of the second receiving groove 321 so that the flow of the lowest reinforcing plate 330 is prevented.

Each reinforcing column 340 is inserted into a plurality of reinforcing column insertion grooves 331a formed on the upper surface of the reinforcing plate 330 and vertically installed. The reinforcing plate 330 is seated on the upper end of the reinforcing column 340. That is, the reinforcing plate 330 and the reinforcing column 340 are alternately stacked to form a plurality of unit layers, and the upper surface of the reinforcing plate 330 constitutes the bottom surface of each unit layer.

The load is concentrated on the reinforcing portion 331 of the lowest reinforcing plate 330 since the plurality of reinforcing pillars 340 are seated on the reinforcing portion 331 of the reinforcing plate 330. Therefore, it is preferable that the second support 310 supporting the second base 320 is also densely arranged in a region corresponding to the reinforcement portion 331 of the lowermost reinforcement plate 330.

A plurality of reinforcing posts 340, which are erected vertically together on one reinforcing plate 330 and support the reinforcing plate 330 on the upper layer, are spaced apart from each other to form a gap therebetween, The seawater can be circulated through the clearance between the reinforcing pillars 340.

The plurality of reinforcing plates 330 exposed on the sea surface constitute the view layer 301. A railway 350 is installed along the perimeter of each of the reinforcing plates 330 to prevent safety accidents, You can enjoy watching. A plurality of vertical bars 351 may be provided along the upper edge of the reinforcing plate 330 so as to be spaced apart from each other and each of the vertical bars 351 may be connected with a rope 352 or a chain, Can be formed. As another example, it is possible to construct a window or a wall along the perimeter of one view layer 301 to divide the inside and the outside, and to install a resting facility or a leisure facility such as a restaurant or a cafe.

Here, in the embodiment shown in the drawings, the unit layer constituting the view layer 301 is configured to have the same structure as the below-described reinforcing layer 302, but in the case of the view layer 301, In order to utilize it as a space for installation, it is possible to arrange the gap between the reinforcing pillars differently from the reinforcing layer.

The uppermost reinforcing plate 330 on which the lighthouse 10 is installed may have a width corresponding to the width of the extending portion 332 of the reinforcing plate 330 It can be formed relatively narrow.

On the other hand, a plurality of unit layers, which are located below the observation layer 301 and are submerged below the sea surface, form a reinforcing layer 302 for supporting the observation layer 301. It is preferable that the reinforcing layer 302 is constructed by appropriately selecting the number of layers according to the depth of the water. Like the above-described outlook layer 301, the reinforcing plate 330 and a plurality of reinforcing pillars 340 ) Constitute a unit layer. The plurality of reinforcing pillars 340 are spaced apart from each other so as to form a clearance of a predetermined distance therebetween, and seawater is freely circulated through the clearance.

In the multi-layer structure including the reinforcing layer 302 and the outlook layer 301, it is preferable that a passageway 360 communicating the upper layer and the lower layer is formed so that each layer can be moved up and down. As shown in the figure, a passage 360 is vertically communicated with one side of the extension portion 332 of the reinforcing plate 330, and a ladder 361 can be installed in each passage 360 have. As another example, a passageway 360 may be formed around the central reinforcing column 340 and a spiral step (not shown) may be provided along the perimeter thereof, or an elevator (not shown) may be installed. The user can freely use various resting facilities, sightseeing and leisure facilities installed on each of the view layers 301 by moving up and down through the passage 360.

The marine resort structure 100 according to the embodiment of the present invention can be installed solely on the sea, and in this case, a mooring facility for berthing the ship can be installed in a part of the view layer 301 of the auxiliary tower 300 have. As another example, it is also possible that the marine resort structure 100 is installed at the end of the breakwater 400 extending from land to sea, where the users can walk through the breakwater 400 or through the vehicle to the auxiliary tower 300, The viewer may enter the view layer 301 of FIG.

The main tower 200 and the auxiliary tower 300 are connected to each other by a breakwater 400 and a part or entire section of the breakwater 400 can be formed as a resting and recreation facility such as a ship berthing facility, have.

At this time, a known breakwater structure may be applied to the breakwater 400, and it is preferable that seawater can pass through the breakwater 400 as in the embodiment shown in the drawing. In the embodiment shown in the drawing, a base block 410 to which a protrusion 411 is fixed on a bottom surface of a seabed, a bottom plate 420 to be seated on the upper side of the base block 410, And a cover plate 440 covering the upper side of the unit block 430. The unit block 430 includes a plurality of unit blocks 430, At this time, the unit block 430 is formed in a lattice form in which a space portion is formed so that seawater can pass through.

On the other hand, an underwater image acquisition device (not shown) capable of observing a marine ecosystem such as a terrain or a fish in the water is installed in the facility layer 201 of the main tower 200 or the view layer 301 of the auxiliary tower 300 . The underwater image capturing device may be, for example, an underwater camera or a device such as a sonar for detecting the object of the seabed by ultrasonic wave emission. The user may view the underwater scenery from the facility layer 201 or the view layer 301 .

In addition, it is difficult to confirm the light of the lighthouse (10) in the distant sea during the dark night, and since the ship can not decelerate suddenly after approaching close, And an alarm (not shown) for emitting a warning sound when the ship is approaching the ship.

FIG. 6 is a schematic diagram of a maintenance and measurement system for a marine resort structure according to an embodiment of the present invention.

According to an embodiment of the present invention, the settlement, inclination, wave pressure, wave height, etc. of a marine resort structure 100 including the main tower 200, the auxiliary tower 300 and the breakwater 400 are measured, A maintenance measurement system is installed at one side of the waterfront resort structure 100 to determine the damage state of the structure 100 and to determine an inspection time so that an appropriate response according to the damage can be promptly processed.

6, a maintenance measurement system according to an embodiment of the present invention includes a plurality of measurement devices 112, 114, 116, and 118 installed at a plurality of places in a sea resort structure 100, a communication device 120, a storage device 130, A management apparatus 140 and an administrator terminal 160 connected to the management apparatus 140 via the network 150. [

Here, the plurality of measurement devices 112, 114, 116, and 118 include a structure sinking system 112 for measuring settlement of the sea resort structure 100, a structure inclination meter 114 for measuring the slope of the sea resort structure 100, A wave pressure meter 116 for measuring the wave pressure of a wave that hits the sea resort structure 100 and a wave height meter 118 for measuring the wave height of the waves pushed by the sea resort structure 100, And can be installed in a plurality of places.

The communication device 120 is in short-range communication with each of the measurement devices 112, 114, 116 and 118 and can receive measurements from the respective measurement devices 112, 114, 116 and 118 at predetermined intervals. To this end, the communication apparatus 120 may be connected to each of the measurement apparatuses 112, 114, 116 and 118 through an Ethernet network or may be connected to each of the measurement apparatuses 112, 114, 116 and 118 via Bluetooth, Zigbee, Near Field Communication (NFC) Or the like.

The storage device 130 stores the measurement value currently received through the communication device 120 together with the reception time information. That is, the storage device 130 stores the settlement measurement value, the slope measurement value, the wave pressure measurement value, the peak measurement value, etc. of the offshore resort structure 100 measured through the communication device 120 together with the time information at the time of reception do. At this time, it is preferable that the storage device 130 stores the location information of the sea resort structure 100 of each measurement device 112, 114, 116, 118 together with the received measurement value.

FIG. 7 is a schematic view showing an example of the management apparatus of FIG. 6, and FIG. 8 is a diagram showing an example of a breakage state determination reference range, which is an example of matching and storing breakage rates according to the change amounts of slope.

The management device 140 is capable of communicating with the maritime resort structure 100 based on measured values currently received from each of the measurement devices 112, 114, 116 and 118 via the communication device 120 and measurements for a certain period of time stored in the storage device 130. [ And calculates the time for inspection. 7, the management apparatus 140 includes a reference range storage unit 141, a reference range comparison unit 142, and a damage condition determination unit 143. [

The reference range storage unit 141 sets and classifies a range of at least one of the set change amount, the inclination change amount, the wave pressure, and the wave height in a plurality of steps, and matches the breakage ratio to each of the classified steps, . For example, as shown in FIG. 8, the reference range storage section 141 classifies the change amount of the inclination of the sea resort structure 100 with respect to the reference sea level into various stages, The failure rate indicating how much the sea resort structure 100 is damaged can be matched and stored.

8 illustrates that the reference range storage 141 stores the gradation change amounts in five grades and stores the corresponding failure rates corresponding to the graded gradations in a matching manner, The slope change amount can be classified into more detailed steps and the breakage rates can be matched and stored in each step.

In this way, the reference range storage unit 141 can also classify each of the settlement change amount, wave pressure, and wave height into a plurality of steps, and store the matching failure rates corresponding to the respective steps. At this time, the reference range storage unit 141 stores the breakage rates up to the present in the sea resort structure 100 for each settlement and stores the settlement change amount and the slope change amount. For the wave pressure and wave height, In accordance with the measured value, the breakage rate of the offshore resort structure 100 at present can be matched and stored for each stage.

Here, each breakage rate is a percentage of breakage of the offshore resort structure 100 due to a change in slope, a change in settlement, a wave pressure, a wave height, etc., and the breakage rate can be statistically obtained.

The reference range comparison unit 142 compares the currently received measurement value with the reference range stored in the reference range storage unit 141 via the communication device 120. [

The damage condition determining unit 143 determines whether the measurement value currently received through the communication device 120 is within the reference range stored in the reference range storage unit 141, (100). For example, assuming that the slope measurement value currently received through the communication device 120 is 1.2, the damage state determination unit 143 determines that the currently received slope measurement value corresponds to the second step in the case of FIG. 8 It can be judged that the marine resort structure 100 is broken by 0.2% to 3%.

At this time, the damage state determination unit 143 determines the damage state based on the damage rate corresponding to the step corresponding to the measurement value currently received through the communication device 120, ) May be determined. That is, when the measurement value received through the communication device 120 is the wave pressure measurement value or the wave height measurement value, the failure state determination unit 143 determines the wave condition value or the wave height measurement value based on the previous wave pressure measurement value or the wave height measurement value, Accumulating the breakage rates of the marine resort structure 100 by accumulating the breakage rates corresponding to the accumulated wave pressures or the breakage rates corresponding to the wave heights and adding the breakage rates corresponding to the currently received wave- It is possible to judge the breakage state to the present.

In addition, the damage state determination unit 143 may determine the total damage state of the sea resort structure 100 up to the present by summing the failure states determined by the measured values of the subsidence, slope, wave pressure, and wave height. For example, if the breakage state determined by the settlement measurement value is 0.2%, the breakage state judged by the slope measurement value is 0.1%, the breakage state judged by the wavemeasurement measurement value is 0.2% Assuming that the breakage state to the present determined by the measured value is 0.05%, the breakage state determination unit 143 may calculate the breakage state of the sea resort structure 100 by 0.55% have.

9 is a schematic view showing another example of the management apparatus of Fig.

9, the management apparatus 140 may include a calculation unit 144, a remaining time calculation unit 145, and a message transmission unit 146. [

The calculation unit 144 calculates an average change amount of the measured value for a predetermined period and an average change amount of the broken state according to the measured value change with respect to each measured value received at the set period and stored in the storage unit 130. [ For example, the three most recent tilt measurement values among the tilt measurement values received at weekly intervals and stored in the storage device 130 are 0.15 °, 0.16 °, and 0.17 °, respectively, and the corresponding breakage rates are 0.14%, 0.16% , And 0.18%, the calculation unit 144 can calculate that the average change amount of the gauged measurement value at the week interval is 0.01 ° and the average change amount of the damage state according to the measured value change is 0.02%.

The remaining time calculating section 145 calculates the remaining time until the failure state of the offshore resort structure 100 becomes a specific value based on the average change amount of the measured value and the average change amount of the failure state calculated by the calculation section 144 Can be calculated. For example, as described above, when the average change amount of the measured value at the week interval calculated by the calculation unit 144 is 0.01 and the average change amount of the broken state according to the measured value change is 0.02%, the remaining time calculation unit 145) can be predicted to take 50 weeks until the damage condition of the marine resort structure 100 becomes 1% due to the inclination change. Among them, since the breakage rate to date is 0.18%, the marine resort structure 100) is 1%, the remaining time is 41 weeks.

The message transmission unit 146 may transmit a check time notification message to the administrator terminal 160 via the network 150 based on the remaining time calculated by the remaining time calculation unit 145. [ At this time, the network 150 may be a wired network using UTP or optical fiber cable, a short-range wireless communication network using Bluetooth, NFC (Near Field Communication), Zigbee, or the like, or a Code Division Multiple Access ), WCDMA (Wideband CDMA), and Global System for Mobile communication (GSM). The administrator terminal 160 includes not only a computer connected through a wired network, but also a mobile phone, PDA (Personal Digital Assistant), etc. connected through a mobile communication network, and a smart phone and a notebook connected through a wireless Internet.

10 is a schematic view showing still another example of the management apparatus of Fig.

10, the management apparatus 140 may include a message transmission unit 146, an absolute reference storage unit 147, a measured value comparison unit 148, and a reception period changing unit 149. Here, the message transmitting unit 146 has the same function as the message transmitting unit 146 of FIG.

The absolute reference storage 147 stores the absolute reference for at least one of subsidence, slope, wave pressure, and wave height of the offshore resort structure 100. At this time, the absolute reference storage unit 147 necessarily stores the settlement measurement value, the slope measurement value, the wave pressure measurement value, the wave height measurement value, and the like, which must be inspected by the administrator and the repair of the resort structure 100, .

The measured value comparison unit 148 compares the currently received measurement value via the communication device 120 with the corresponding absolute reference stored in the absolute reference storage unit 147. [ For example, if the measured value currently received via the communication device 120 is a tilt measurement value, the tilt measurement value is compared with a corresponding tilt absolute reference. The message transmitting unit 146 transmits an emergency status message to the administrator terminal 160 via the network 150 when the measurement value comparison unit 148 determines that the measured value currently received exceeds the absolute reference. In this case, the message transmitting unit 146 includes the position corresponding to the measured value exceeding the absolute reference and the type of the signal corresponding to the measured value (for example, a subsidence signal, a slope signal, etc.) . In this way, when an unexpected natural disaster such as a typhoon, an earthquake, or a tsunami causes sudden changes in subsidence, slope, wave pressure, and digging, the administrator can be notified of the situation and promptly respond.

If it is determined by the measured value comparison unit 148 that the measured value received via the communication device 120 exceeds the absolute reference stored in the absolute reference storage unit 147, 120 can be changed to be smaller than the existing reception period. If the settlement measurement value, the slope measurement value, the wave pressure measurement value, and the peak measurement value suddenly change due to a natural disaster such as a typhoon, an earthquake or a tsunami and exceeds the absolute reference, By reducing the reception period, the administrator can pay more attention to the situation change.

The administrator terminal 160 may be connected to the management apparatus 140 via the network 150 and may output the damage status and the inspection time of the offshore resort structure 100 determined by the management apparatus 140.

11 is a schematic view of an automatic management system for a marine resort structure according to an embodiment of the present invention.

11, an automatic management apparatus 500 according to an embodiment of the present invention includes a measurement value receiver 510, a measurement value storage 520, a damage status determiner 530, a message transmitter 540, A reference range storage unit 550, and a reference range comparison unit 560.

The measurement value receiving unit 510 receives measurement values of at least one of subsidence, inclination, wave pressure, and wave height at each location of the marine resort structure 100 from a plurality of sensors installed at a plurality of locations in the marine resort structure 100 Period. To this end, sensors such as a structure sinking system, a structure inclination system, a wave pressure meter, a wave height meter, and the like are installed at a plurality of places of the sea resort structure 100, and the measurement value receiving unit 510 can communicate with such sensors by wire or wireless .

The measurement value storage unit 520 stores measurement values received through the measurement value reception unit 510 together with reception time information. That is, the measurement value storage unit 520 stores time information of a settlement measurement value, an inclination measurement value, a wave pressure measurement value, a wave height measurement value, and the like of the sea resort structure 100 measured through the measurement value reception unit 510 ≪ / RTI >

The damage state determination unit 530 determines the damage state of the sea resort structure 100 based on the measurement values currently received through the measurement value reception unit 510 and the measurement values stored in the measurement value storage unit 520 for a predetermined period of time State.

The message transmission unit 540 may transmit the damaged state of the marine resort structure 100 determined by the damage state determination unit 530 to the administrator terminal 160 connected through the network. For this, the message transmission unit 540 stores the identification number of the registered administrator terminal 160.

In order to assist the damage condition determination unit 530 to determine the damage condition of the marine resort structure 100, the reference range storage unit 550 stores the settlement change amount, the slope change amount, the wave pressure, The range may be stored in a reference range of the damage condition for determining the damage condition of the at-sea resort structure 100 by matching the breakage rates at each of the classified steps.

The reference range comparison unit 560 compares the currently received measurement value with the reference range stored in the reference range storage unit 550 through the measurement value reception unit 510.

In this case, the damage state determination unit 530 uses the corresponding failure rate according to which stage of the reference range stored in the reference range storage unit 550, through the measured value reception unit 510 So that it is possible to determine the damage state of the offshore resort structure 100. In addition, the damage state determination unit 530 may determine that the measured value received through the measurement value reception unit 510 is in a non-degraded condition based on the failure rate corresponding to the corresponding step in the reference range, 100) may be determined.

That is, when the measurement value received through the measurement value receiving unit 510 is the wave pressure measurement value or the wave height measurement value, the failure state determination unit 530 determines the wave condition of the sea resort structure 100 ) And accumulates and stores the breakage rates of the marine resort structure 100 by accumulating the breakage rates corresponding to the accumulated wave pressures or the breakage rates corresponding to the wave heights, It is possible to judge the state of damage to the present.

The breakage state determination unit 530 adds up the breakage states determined by the measured values of the subsidence, the slope, the wave pressure, and the wave height to determine the overall breakage state of the sea resort structure 100 up to the present.

12 is a schematic view of an automated management system for a marine resort structure according to another embodiment of the present invention.

12, the automatic resort management system 600 for a marine resort structure according to another embodiment of the present invention includes a measurement value receiving unit 610, a measurement value storage unit 620, a damage state determination unit 630, A calculation unit 640, a calculation unit 650, and a remaining time calculation unit 660.

The functions and operations of the measured value receiving unit 610, the measured value storing unit 620, the damaged state determining unit 630 and the message transmitting unit 640 are the same as those of the measured value receiving unit 510, The breakdown state determination unit 530, and the message transmission unit 540, the description of the overlapping contents will be omitted.

The calculation unit 650 calculates an average change amount of the measured value during a predetermined period and an average change amount of the broken state according to the measured value change with respect to each measured value received at the set period and stored in the measured value storage unit 620 . For example, if the tilt measurement values received at intervals of one week and stored in the storage device 130 are 0.15 °, 0.16 °, and 0.17 °, respectively, and the corresponding breakage rates are 0.14%, 0.16% 0.18%, the calculation unit 650 calculates the average change amount of the inclination measured value at a week interval of 0.01 ° and the average change amount of the broken state according to the measured value change as 0.02%, as described with reference to FIG. 9 .

The remaining time calculating unit 660 calculates the remaining time until the breakage state of the offshore resort structure 100 becomes a specific value based on the average change amount of the measured value and the average change amount of the breakage state calculated by the calculation unit 650 Can be calculated. For example, as described above, when the average change amount of the measured value at the week interval calculated by the calculation unit 650 is 0.01 and the average change amount of the broken state according to the measured value change is 0.02%, the remaining time calculation unit 660) can be predicted to take 50 weeks until the damage state of the marine resort structure 100 is 1% due to the inclination change. Among them, since the breakage rate to date is 0.18%, the marine resort structure 100) is 1%, the remaining time is 41 weeks.

The message transmission unit 640 can transmit a check time notification message to the administrator terminal through the network based on the remaining time calculated by the remaining time calculation unit 660. [

13 is a schematic view of an automated management system for a marine resort structure according to another embodiment of the present invention.

The automatic resort management system 700 of the present invention includes a measurement value receiver 710, a measurement value storage 720, a damage state determiner 730, a message transmitter 740, A reference storage unit 750, an absolute reference comparison unit 760, and a reception period changing unit 770.

The functions and operations of the measured value receiving unit 710, the measured value storing unit 720, the damaged state determining unit 730 and the message transmitting unit 740 are the same as those of the measured value receiving unit 510, The breakdown state determination unit 530, and the message transmission unit 540, the description of the overlapping contents will be omitted.

The absolute reference storage unit 750 stores the absolute reference to at least one of subsidence, slope, wave pressure, and wave height of the marine resort structure 100.

At this time, the absolute reference storage unit 750 necessarily stores the settlement measurement value, the slope measurement value, the wave pressure measurement value, the wave height measurement value, and the like, which are required to be inspected by the administrator and the maintenance of the offshore resort structure 100 .

The absolute reference comparison unit 760 compares the currently received measurement value with the absolute reference stored in the absolute reference storage unit 750 through the measurement value reception unit 710. [ For example, when the measured value currently received through the measured value receiving unit 710 is a tilt measurement value, the tilt measurement value is compared with a corresponding tilt absolute reference.

If it is determined that the measured value currently received by the absolute reference comparison unit 760 exceeds the absolute reference, the message transmission unit 740 may transmit an emergency status message to the administrator terminal 160 connected through the network. In this case, the message transmission unit 740 may include the position corresponding to the measured value exceeding the absolute reference and the type of the signal corresponding to the measured value (for example, a subsidence signal, a slope signal, etc.) send.

If it is determined by the absolute reference comparison unit 760 that the measured value received through the measured value receiving unit 710 exceeds the absolute reference stored in the absolute reference storage unit 750, the receiving period changing unit 770 It is possible to control the measurement value receiving unit 770 to change the measurement value reception period to be smaller than the existing reception period. If it is determined that the settlement measurement value, the slope measurement value, the wave pressure measurement value, the peak measurement value, and the like exceed the absolute reference, the reception period changing unit 770 decreases the reception period of the measurement value, So that more attention can be paid to the situation change.

The marine resort structure 100 according to an embodiment of the present invention can enjoy various types of marine leisure such as fishing, scuba diving, swimming and the like in one place while enjoying marine sightseeing while staying for a predetermined period, Can be used as a resting and recreational facility where visitors can experience a different experience.

In addition, since the supporting layer 202 of the main tower 200 and the reinforcing layer 302 and the breakwater 400 of the auxiliary tower 300 are constructed so as not to interfere with the flow of the current, the surrounding marine ecosystem can be preserved.

In addition, since the lighthouse 10 is installed not only with the lighthouse 10 but also with a complex resting and recreation facility, the lighthouse 10 can be used to guide the safe operation of the ship It is possible to generate profits by tourism and leisure industry.

In addition, it is possible to measure settlement, inclination, wave pressure, wave height, etc. and determine the breakage state thereof, so that it is possible to quickly take measures for maintenance.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: Lighthouse 100: Offshore Resort Structure
200: main tower 201: facility floor
202: support layer 210: first support
220: first base 230: support plate
240: support column 300: auxiliary tower
301: view layer 302: reinforcing layer
310: second support base 320: second base
330: reinforcing plate 340: reinforcing column
400: Breakwater 500,600,700: Automatic management device

Claims (18)

Main tower installed at sea;
An auxiliary tower disposed radially outward of the main tower around the main tower; And
And a plurality of breakwaters connecting the main tower and the auxiliary tower,
The main tower includes a first base that is seated on the sea floor, a support layer formed as at least one unit layer above the first base and immersed below the sea level, and at least one unit layer formed on the support layer, And a plurality of supporting columns spaced apart from each other such that a gap is formed between the supporting columns and the bottom plate of the supporting plate, And a flange portion extending outwardly of the support portion so as to have a thickness smaller than that of the support portion along the periphery of the support portion, wherein the support portion of the lowermost support plate is supported by the first receiving groove on the upper side of the first base And the flange portion of the lowermost support plate is inserted into the first Along the sea resorts structure characterized in that the close contact with the image-side surface of the first base. The method according to claim 1,
Wherein accommodation facilities are installed in the main tower and recreational facilities or leisure facilities are installed in the auxiliary towers. The method according to claim 1,
Wherein a park, a walkway, a fishing boat, or a ship berthing facility is installed on one side of the breakwater. The method according to claim 1,
Wherein the main tower and the auxiliary tower are multi-layer structures having a plurality of unit layers. The method of claim 4,
Wherein a main lighthouse is installed on the uppermost layer of the main tower and an auxiliary lighthouse is installed on the uppermost layer of at least one of the plurality of auxiliary towers. The method according to claim 1,
Wherein at least one room formed in the facility layer is provided with a slide extending in the sea level direction. delete The method according to claim 1,
Wherein the support plate comprises a plurality of unit plates joined together on the same plane. delete The method according to claim 1,
And a plurality of support post insertion grooves into which one end of the support post is inserted are formed on one surface of the support plate. delete The method according to claim 1,
Wherein the first base is seated on a plurality of supports mounted on the seabed. The method of claim 4,
Wherein the auxiliary tower comprises a reinforcing layer formed of at least one unit layer and submerged below the sea surface, and a view layer formed as at least one unit layer above the reinforcing layer and exposed over the sea surface. 14. The method of claim 13,
Wherein the unit layer constituting the reinforcing layer comprises a reinforcing plate and a plurality of reinforcing pillars supporting the bottom surface of the reinforcing plate, wherein the plurality of reinforcing pillars are spaced from each other to form a gap therebetween. 15. The method of claim 14,
Wherein the reinforcing plate includes a reinforcing portion formed at the center and an enlarged portion formed to extend outwardly of the reinforcing portion along the periphery of the reinforcing portion. 14. The method of claim 13,
And an underwater image acquisition device for displaying an underwater object in real time on one of the view layers. The method of claim 5,
Wherein the main lighthouse or the auxiliary lighthouse is provided with a detection sensor for detecting the approach of the ship and an alarm for emitting a warning sound when the ship is approaching. The method according to claim 1,
A plurality of measuring devices installed at a plurality of places in the main tower or the auxiliary tower and measuring at least one of subsidence, inclination, wave pressure and wave height for each of the locations;
A communication device for performing short-distance communication with the measurement device by wire or wireless;
A storage for storing measured values received via the communication device; And
And a management device for determining a failure state of the main tower or the auxiliary tower based on the measured value, wherein the management device is configured to determine at least one of a settlement change amount, an inclination change amount, a wave pressure, A reference range storing unit for storing the measured values received through the communication device in the reference range storing unit by setting and classifying the ranges, A reference range comparing unit for comparing the reference value with a reference range and determining a failure state using a corresponding failure rate according to which of the reference ranges stored in the reference range storage unit is a measurement value currently received via the communication device And a breakage state determination unit for determining a breakage state of the water.

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