KR20250030125A - Standing type overpass and flood prevention wall - Google Patents

Abstract

The present invention relates to a concrete barrier wall structure installed on the embankment top of a river or seaside, and an erected wave-breaking and flood-prevention wall integrated therewith.
The present invention comprises a concrete structure installed on the embankment of a river or a seaside and having a slope toward the river or seaside and having a predetermined height, a door frame is installed on the upper side of the slope of the concrete structure, the door frame is fixed by a reinforcing support inside the concrete structure, a barrier wall is installed to rotate and fall over or stand up on the upper front side of the door frame, a triangular fall-prevention support member is installed on the rear side of the barrier wall so that the fall-prevention support member is supported by the upper side of the door frame when the barrier wall is erected, a cylinder room is installed in a form embedded in the slope of the concrete structure, the front of the cylinder room is open toward the front of the slope so as to be opened and closed by an inspection cover, and a hydraulic cylinder installed vertically in the cylinder room causes the barrier wall to fall in the same direction as the slope or to stand up vertically on the upper side of the concrete structure.

Description

{Standing type overpass and flood prevention wall}

The present invention relates to a concrete barrier wall structure installed on the embankment top of a river or seaside, and an erecting wave-breaking and flood-prevention wall integrated therewith.

In general, concrete barrier walls installed on river embankments or along the coast are installed to prevent floods, tsunamis, and wave overtopping. The height and thickness of the concrete barrier walls are determined by calculating the estimated frequency of flooding in 50 to 100 years before installation. However, recently, due to rapid climate change caused by global warming, flood levels have risen beyond the concrete barrier walls, and tsunamis and wave overtopping have occurred, causing serious human and material damage.

In order to prevent such natural disasters, the height of existing concrete barriers (flood prevention walls, wave overtopping prevention walls) is increased while the thickness is changed for construction, or a transparent barrier of a certain height is installed separately on top of the existing concrete barrier to increase the height while guaranteeing the view, or the existing concrete barrier is removed and a rising/falling barrier or a standing barrier that is normally laid down but rises, lowers, or stands up when a flood, tsunami, or wave overtopping is expected is installed.

Structures such as concrete barriers for disaster prevention are subject to various conditions in order to achieve their unique installation purposes. These conditions include the difficulty of having to first review construction costs, appropriateness of the installation location, safety, durability, etc., while also necessarily having to review the view and landscape.

Among the prior technologies for preventing wave overtopping, floods, and tsunamis that exceed existing expectations, the method of changing the height and thickness of concrete barriers is excellent in terms of economy and safety, but when installed over 1 m, the opaque nature of concrete reduces the view and landscape, making it difficult to implement due to opposition from residents. In addition, the method of installing a transparent barrier on top of an existing concrete barrier has the advantage of a short construction period, low cost, and easy installation in narrow spaces such as river embankments or coastal roads because the transparent barrier is installed using polycarbonate, tempered laminated glass, and metal structures. However, it is vulnerable to deterioration of the transparency of the transparent material and damage due to impact, and in particular, when used as a wave overtopping prevention wall, it is vulnerable to damage due to the flying of stones by typhoons and the impact of stones accompanied by waves.

And, among the prior technologies for preventing wave overtopping, floods, and tsunamis, the rising and falling type barriers are mainly installed in coastal cargo yard and riverside entrances and exits where vehicle traffic is required, and the barriers are normally underground, and when floods, wave overtopping, and tsunamis are expected, the barriers are raised and moved above ground. However, the civil engineering and mechanical installation costs are high, and maintenance of the driving devices installed underground is difficult. In addition, durability is low, and since long-distance construction is difficult, pillars are installed at a distance of about 10 to 15 meters, so there is a problem of poor views and scenery. The standing wave overtopping and flood prevention barriers are installed in coastal walkways, cargo yard vehicle entrances and exits, and river walkways. Since the barriers are normally laid horizontally on the ground, they are used as pedestrian walkways, vehicle entrances, etc., and when floods, wave overtopping, and tsunamis are expected, the barriers are raised and moved up. They do not impair the view in normal times, and they are safe and durable. However, since the barriers must be installed horizontally to the ground, It is difficult to install on narrow coasts and river embankments, and from an economic perspective, it is less economical than installing concrete or transparent barriers.

[Document 1] Patent Registration No. 10--2048026 (announced on December 2, 2019) [Document 2] Patent Registration No. 10-1839094 (announced on March 15, 2018) [Document 3] Patent Registration No. 10-1849368 (announced on April 16, 2018) [Document 4] Patent Registration No. 10-1328616 (announced on November 13, 2013)

The present invention is to solve the above-mentioned problem by installing a barrier wall of 1 m or more on a seashore or river embankment, making it easy to construct in a narrow space, minimizing the impact on the view and landscape, reducing the economic burden, and improving durability, by using a concrete structure as the lower structure and installing an erecting barrier wall on the upper and front parts thereof.

The structure of installing the concrete structure of the present invention at the bottom of a defensive wall is such that the impact of the view and landscape caused by the concrete structure on the normal view is minimized at a height of less than 1 m to 1.2 m, and the erected defensive wall, which is installed at an angle of 1 m to 1.2 m on the upper part and front part of the concrete structure, that is, in the direction of the outer side of a riverbank or the outer side of the sea, or parallel to the road surface, is erected when wave overtopping, flooding, or tsunami are expected.

In addition, the present invention solves the problems of the rising/falling type barriers, such as high cost, difficult glass management, and short durability, by applying a concrete structure to 30% to 60% of the total height of the barrier, thereby solving economic feasibility, while installing the barrier on the ground to make maintenance easy, and in order to solve the problem of securing construction space for the existing standing barrier (the problem of requiring an installation width of 2.5 m or more for the installation of a standing barrier that is 1 m or more in height), the construction width is approximately 1.5 m for easy installation, and in addition, in order to prevent damage by stones, the barrier material is selected from iron, stainless steel, FRP, etc. and manufactured.

The present invention comprises a concrete structure installed on the embankment of a river or a seaside and having a slope toward the river or seaside and having a predetermined height, a door frame is installed on the upper side of the slope of the concrete structure, and the door frame is fixed by a reinforcing support inside the concrete structure, a barrier wall is installed to rotate and fall over or stand up on the upper front side of the door frame, a triangular fall-prevention support member is installed on the rear side of the barrier wall so that the fall-prevention support member is supported by the upper side of the door frame when the barrier wall is erected, a cylinder room is installed in a form embedded in the slope of the concrete structure, and the front side of the cylinder room is open toward the front of the slope so as to be opened and closed by an inspection cover, and a hydraulic cylinder installed vertically in the cylinder room causes the barrier wall to fall in the same direction as the slope or to stand up vertically on the upper side of the concrete structure, so that the barrier wall, which has been fallen in a form covering the slope of the concrete structure, is erected vertically on the upper side of the concrete structure by the hydraulic cylinder.

The present invention provides a method for stably supporting a defense wall when it is erected by an anti-fall support, and a hydraulic cylinder installed in a cylinder room is covered with a cylinder moving cover to protect it from leakage, while a moving cover is installed on the upper part of the cylinder room, which moves back and forth according to the operation of the hydraulic cylinder and covers the upper part to prevent the inflow of rainwater or seawater, and an inspection cover is exposed on the front of the inclined surface to enable maintenance of the hydraulic cylinder.

In the defensive wall of the present invention, a wave direction change plate is installed forward at an angle of 20 to 80 degrees to change the direction of the overtopping wave, and a water resistance rubber is installed on the lower rear portion of the defensive wall and the bottom surface of the anti-tip support to create a water resistance when the defensive wall is erected.

Another embodiment of the present invention comprises a concrete structure having a predetermined height and installed on a levee of a river or a seaside, a door frame is installed on the upper side of the concrete structure, the door frame is fixed to a reinforcing support inside the concrete structure, a barrier wall is coupled to the upper front side of the door frame to rotate and fall or stand up, a floating support is installed on the rear side of the barrier wall to move along a driving guide installed horizontally on the upper side of the concrete structure and to stand up the barrier wall while supported by a stopper, a support cover is placed on the upper part of the floating support, the rear of the support cover is rotatably connected to the stopper, a slide bar is installed in a direction perpendicular to the side of the driving guide, the slide bar is moved back and forth by a hydraulic cylinder installed horizontally while supported by a floating roller, and a safety pin is installed on the upper side of the slide bar to be fitted into a pin hole formed on the lower side of the floating support, and when the floating support is supported by the stopper, the slide bar is moved so that the safety pin is fitted into the pin hole. Meanwhile, the floating support is laid down when the slide bar is retracted and the safety pin is removed from the pin hole, and the concrete structure is provided with a cylinder room in which a hydraulic cylinder for overturning or erecting the barrier wall is installed, and the barrier wall overturned by the hydraulic cylinder is supported horizontally by a support wall on the concrete structure, so that the barrier wall can be used as a pedestrian passageway because a safety guard is installed on the outside and overturned horizontally with the upper surface of the concrete structure.

Here, the cylinder room is manufactured in a form built into the concrete structure, but the front of the cylinder room is installed so that the front cylinder cover is exposed at the front of the concrete structure, so that it has a form that is sunken inward at the front of the concrete structure, but the front cylinder cover is always exposed, and the upper side of the cylinder room is also installed so that it is always exposed at the upper side of the concrete structure.

In the present invention, when a defensive wall is erected, a movable support is erected and moves along a driving guide and is supported by a stopper, and when the movable support is erected during this process, a support cover covering the movable support is erected based on the stopper, and the movable support is erected. Conversely, when the defensive wall is overturned, the movable support is folded and the support cover covers the movable support, and overturning is achieved, so that when the defensive wall is overturned, the movable support is not exposed while covered by the support cover.

When the barrier wall of the present invention is erected, the floating support is supported by the stopper and is erected, and at this time, the hydraulic cylinder is operated to move the slide bar forward along the floating roller, and the safety pin installed on the slide bar is inserted into the pin hole formed on the lower side of the floating support, thereby solving the problem of the barrier wall being overturned to the front due to a backwind generated on the rear side of the barrier wall. In order to overturn the barrier wall, the slide bar is retracted to cause the safety pin to be removed from the pin hole, and then the hydraulic cylinder is operated to overturn the barrier wall.

To this end, a slide bar is installed in a direction perpendicular to the side of a driving guide that moves a movable support, and the slide bar is moved back and forth by a hydraulic cylinder while supported by a movable roller. A safety pin that fits into a pin hole formed on the lower side of the movable support is installed on the upper side of the slide bar, and when the movable support is supported by the stopper, the slide bar is moved so that the safety pin fits into the pin hole or the safety pin is removed from the pin hole.

And, the hydraulic cylinder for overturning and erecting the defensive wall is installed in the cylinder room, and the cylinder room is covered with a front cylinder cover with the front exposed at the front of the concrete structure, and a floating cover is installed with the upper side of the cylinder room exposed, and the floating cover opens and closes the upper side of the cylinder room according to the forward and backward movement of the hydraulic cylinder, and the floating cover prevents the inflow of seawater or rainwater.

The hydraulic cylinder installed in the cylinder room is covered with a floating cover at the top of the cylinder and a fixed cover at the bottom of the cylinder to prevent rainwater or seawater from flowing in due to cylinder contraction.

The present invention is to install a standing defensive wall on the upper part and front part of a concrete structure as a substructure on the embankment of a river or seaside, thereby facilitating construction in a narrow space, minimizing the impact on the view and landscape, reducing the economic burden, and improving durability.

The present invention has the effect of solving the problem of blocking the view by increasing the height of a concrete structure to prevent rising waves, and the problem of using a rising/falling barrier wall being high cost, difficult to manage glass, and short durability, and has the effect of solving the problem of the difficulty in securing construction space for the existing standing barrier wall, so that it can be easily installed, and the effect of preventing damage by stones by making the barrier wall out of iron, stainless steel, FRP, etc.

Figure 1 is a side view showing the falling and standing of the first embodiment of the defensive wall of the present invention.
Figure 2 is a perspective view of the cylinder chamber of the first embodiment of the present invention.
Figure 3 is a side view of the cylinder chamber of the first embodiment of the present invention.
Figure 4 is a configuration diagram of a hydraulic cylinder of the present invention.
Figure 5 is a side view of a defensive wall of the first embodiment of the present invention.
Figure 6 is a cross-sectional view of a defensive wall according to the first embodiment of the present invention.
Figure 7 is a diagram showing the erection state of the defensive wall of the first embodiment of the present invention.
Figure 8 is a state diagram of the defensive wall conduction of the first embodiment of the present invention.
Figure 9 is a side view of the installation state of the first embodiment of the present invention.
Figure 10 is a front view of the conductive state of the first embodiment of the present invention.
Figure 11 is a front view of the first embodiment of the present invention in a standing state.
Figure 12 is a side view showing the falling and standing of the second embodiment of the defensive wall of the present invention.
Figure 13 is a diagram showing the erection state of the defensive wall of the second embodiment of the present invention.
Figure 14 is a state diagram of the defensive wall conduction of the second embodiment of the present invention.
Figure 15 is a cross-sectional view of the driving guide installation state of the second embodiment of the present invention.
Figure 16 is a plan view of the conductive state of the second embodiment of the present invention.
Figure 17 is a side view of the conductive state of the second embodiment of the present invention.
Figure 18 is a plan view showing the forward and backward state of the slide bar of the second embodiment of the present invention.
Figure 19 is a cross-sectional view showing the state of installation of the cylinder room of the second embodiment of the present invention.
Figure 20 is a perspective view of the cylinder chamber of the second embodiment of the present invention.
Figure 21 is a front view of the conductive state of the second embodiment of the present invention.
Figure 22 is a front view of the second embodiment of the present invention in a standing state.

The present invention installs a concrete structure of a relatively low height so as not to obstruct the view on the embankment of a river or seaside, and installs an erection-type defensive wall on the top and front of the concrete structure, thereby facilitating construction in a narrow space, minimizing the impact on the view and landscape, reducing installation costs, and improving durability.

In the present invention, a first embodiment in which a concrete structure (20) is installed at a height that does not obstruct the view on the embankment (10) of a river or seaside and an erection type defensive wall (30) is installed on the front side of the concrete structure (20) is described in detail with reference to the attached drawings.

The present invention installs a concrete structure (20) at a height of less than 1 m to 1.2 m on the ceiling of an embankment (10) installed on a river or a seashore, and the concrete structure (20) is low enough not to obstruct the view, and is applied to 30% to 60% of the total height of the defensive wall, and forms a slope (21) of less than 15 degrees to 60 degrees in the direction of the sea toward the river or seashore on one side of the concrete structure (20).

In the concrete structure (20) of the present invention, a door frame (40) is installed in a form in which the door frame (40) is exposed on the upper side, and the door frame (40) is installed in the concrete structure (20) by connecting a reinforcing support (41) so that a solid installation is achieved, a protective wall (30) is connected to the upper front side of the door frame (40) with a hinge (31), and a cylinder room (50) is installed in a form in which an inspection cover (51) is exposed on the inclined surface (21), and a hydraulic cylinder (60) is installed inside the cylinder room (50), and the upper and lower sides of the hydraulic cylinder (60) are respectively connected to the front of the protective wall (30) with a hinge (61) and connected to the floor with a hinge (62), so that the protective wall (30) is vertically erected or overturned along the inclined surface (21) by operating the hydraulic cylinder (60). The configuration of using a barrier (30) to invert or erect the barrier is a known operating method of an erecting barrier.

Here, the size of the reinforcing support (41) that fixes the door frame (40) is determined by examining the load of the defensive wall, wind pressure, water pressure, overflow wave pressure, and flood level, and a sturdy construction is achieved by additionally arranging reinforcing bars when pouring concrete, and the cylinder room (50) is installed as a single unit when pouring concrete.

The cylinder room (50) of the present invention is provided with an inspection cover (51) exposed as an inclined surface (21) as shown in FIGS. 1 to 3, and a floating cover (52) covering the upper part is installed. The floating cover (52) is moved forward and backward while being fitted into a cover guide (53) according to the operating angle of the hydraulic cylinder (60), thereby blocking the upper part of the cylinder room (50) during the erection process of the barrier wall (30), thereby preventing rainwater or seawater from flowing in.

As shown in FIGS. 3 and 4, the hydraulic cylinder (60) is provided with a cylinder bottom fixed cover (65) on the bottom of the hydraulic cylinder (60), and a cylinder top movable cover (66) is provided on the top of the hydraulic cylinder (60). When the hydraulic cylinder (60) is operated, the cylinder top movable cover (66) is extended in a state of being extrapolated to the cylinder bottom fixed cover (65), thereby causing the barrier (30) to fall over or stand up, thereby preventing the hydraulic cylinder (60) from contact with seawater salt and foreign substances, and eliminating cases of it being damaged by being hit by a rock.

In addition, the cylinder room (50) in which the hydraulic cylinder (60) is installed is manufactured from stainless steel or FRP to improve durability and facilitate maintenance through the inspection cover (51), and the fluid cover (52) installed on the upper part of the cylinder room (50) is selectively made of polycarbonate or aluminum to reduce damage from contact with the cover guide (53) when the fluid cover (52) operates.

In the defensive wall (30) of the present invention, a triangular anti-fall support member (35) is installed on the rear side. The anti-fall support member (35) is in contact with the upper side of the door frame (40) when the defensive wall (30) is in an upright state and supports the defensive wall (30), thereby preventing the defensive wall (30) from falling backward due to a wave or tsunami. In addition, a water-stop rubber member (37) is installed on the bottom surface of the anti-fall support member (35) to ensure that water is stopped when the defensive wall (30) is in an upright state.

In addition, a water resistance rubber (36) is installed at the rear lower side of the barrier (30) and the contact area of the door frame (40), so that water resistance is achieved by two water resistance rubbers (36)(37) when the barrier (30) is in an upright state, while the tipping prevention support (35) supports the upper surface of the door frame (40), preventing the barrier (30) from falling over or causing leakage.

In the present invention, when the lower part of the barrier wall (30) is erected, the water resistance rubber (36) is pressed against the front surface of the door frame (40) to prevent the first overturning, and the water resistance rubber (37) is pressed against the upper surface of the door frame (40) to prevent the second overturning.

In the defense wall (30) of the present invention, a wave direction change plate (33) is installed in the front as shown in Fig. 6 to change the direction of the overtopping wave and minimize the amount of overtopping wave. The wave direction change plate (33) is installed at an angle of 20 to 80 degrees.

In this first embodiment of the present invention, when the hydraulic cylinder (60) installed in the cylinder room (50) is operated, the barrier wall (30) rotates around the hinge (31) in front of the door frame (40) and stands vertically on the top of the concrete structure (20) or falls along the inclined surface (21). In this process, when the movable cover (52) moves along the cover guide (53) according to the operating angle of the hydraulic cylinder (60), it covers the top of the cylinder room (50), and the hydraulic cylinder (60) expands and contracts while being guided by the cylinder upper movable cover (66) being extrapolated to the cylinder lower movable cover (65), thereby preventing the hydraulic cylinder (60) from being damaged or contaminated by seawater, etc.

And, in the standing state of the barrier wall (30), the sealing of the index rubber (36) primarily prevents overturning in front of the door frame (40), and the sealing of the index rubber (37) allows the overturn prevention support (35) to be supported on the upper surface of the door frame (40), thereby preventing overturning secondarily.

When the front of the present invention is viewed in the state of the defense wall (30), the embankment (10) that is in contact with the river and seawater is visible at the bottom as shown in FIG. 10, and the rear of the defense wall (30) that has been overturned is visible at the top, and it can be confirmed that anti-overturning supports (35) are installed at regular intervals on the defense wall (30) and hinges (31) are installed at regular intervals on the door frame (40), and it can be confirmed that water-stop rubber (36)(37) that prevents the first and second overturns are installed, and when the front of the defense wall (30) is viewed in the state of the standing state, the front of the defense wall (30) on which the wave direction conversion plate (33) is installed can be confirmed as shown in FIG. 11, and the cylinder room (50) with the inspection cover (51) exposed by the inclined surface (21) of the concrete structure (20) and the door frame (40) can be confirmed at the top, and it can be seen that the embankment (10) is installed at the bottom of the concrete structure (20). Can be.

In this way, the present invention installs a concrete structure (20) at a height that does not obstruct the view on the embankment (10) of a river or seaside, and installs an erected defensive wall (30) on the front side of the concrete structure (20), thereby preventing damage from unexpected waves, tidal waves, floods, etc., while facilitating construction in a narrow space, minimizing the impact on the view and landscape, reducing the economic burden, and improving durability.

A second embodiment of the present invention, in which a concrete structure (20) is installed at a height that does not obstruct the view on the embankment (10) of a river or seaside, and an erection-type defensive wall (30) is installed on the upper surface of the concrete structure (20), is described in detail with reference to the attached drawings.

The present invention installs a concrete structure (20) at a height of less than 1 m to 1.2 m on the ceiling of an embankment (10) installed on a river or a seashore, the concrete structure (20) has a height that does not obstruct the view, and is applied to 30% to 60% of the total height of the defensive wall, and prevents waves from overtopping in the direction of the river or seashore on one side of the concrete structure (20), and allows the rear side of the defensive wall (30) to be used as a walkway when the defensive wall (30) falls.

In the concrete structure (20) of the present invention, a door frame (40) is installed in a form in which the door frame (40) is exposed to the upper side, and the door frame (40) is connected to a reinforcing support (41) so that it is firmly installed in the concrete structure (20), a protective wall (30) is connected to the upper front side of the door frame (40) with a hinge (31), a cylinder room (50) is installed built-in in the concrete structure (20), and the front side of the cylinder room (50) is exposed in the front side of the concrete structure (20), and the upper side is also installed so that it is exposed to the upper side of the concrete structure (20), and a hydraulic cylinder (60) is installed inside the cylinder room (50), and the upper and lower sides of the hydraulic cylinder (60) are respectively connected to the front side of the protective wall (30) with a hinge (62) and connected to the floor with a hinge (61), thereby operating the hydraulic cylinder (60). A method of vertically erecting a defensive wall (30) or inverting it to be supported by a support wall (25) and inverting or erecting the defensive wall (30) using a hydraulic cylinder (60) is known.

Here, the size of the reinforcing support (41) that fixes the door frame (40) is determined by examining the load of the defensive wall, wind pressure, water pressure, overflow wave pressure, and flood level, and a sturdy construction is achieved by additional reinforcement during concrete pouring, and the cylinder room (50) is installed in a built-in form during concrete pouring, but is installed so that the front cylinder cover (55) is exposed when installed by sinking in the front of the concrete structure (20), and the floating cover (52) is exposed while being opened to the upper side of the cylinder room (30).

The cylinder room (50) of the present invention is formed in a square shape with a front cylinder cover (55) installed in a form exposed at the front of a concrete block (20) as shown in FIGS. 19 and 20, and a floating cover (52) covering the upper part is installed, but the floating cover (52) is moved forward and backward while being fitted into a cover guide (53) according to the operating angle of the hydraulic cylinder (60) to block the upper part of the cylinder room (50) during the erection process of the barrier wall (30), thereby preventing rainwater or seawater from flowing in.

Here, the front cylinder cover (55) and the fluid cover (52) are installed so that they can be exposed on the front or top surface of the concrete structure (20).

As shown in FIG. 4, the hydraulic cylinder (60) is provided with a cylinder bottom fixed cover (65) on the bottom of the hydraulic cylinder (60), and a cylinder top movable cover (66) is provided on the top of the hydraulic cylinder (60). When the hydraulic cylinder (60) is operated, the cylinder top movable cover (66) is extended in a state of being extrapolated to the cylinder bottom fixed cover (65), thereby causing the barrier (30) to fall over or stand up, thereby preventing the hydraulic cylinder (60) from contact with seawater salt and foreign substances, and eliminating cases of it being damaged by being hit by a rock.

In addition, the cylinder room (50) in which the hydraulic cylinder (60) is installed is manufactured from stainless steel or FRP to enhance durability, while the front cylinder cover (55) is installed so as to be exposed toward a river or the open sea, thereby facilitating maintenance. The fluid cover (52) installed on the upper part of the cylinder room (50) is made of polycarbonate or aluminum, selectively, to reduce damage from contact with the cover guide (53) when the fluid cover (52) operates.

The defensive wall (30) of the present invention is supported by a support wall (25) as shown in FIGS. 12 to 17 with a driving guide (75) installed, so that when it is in an inverted state, the rear of the defensive wall (30) is used as a walkway, and when it is in an upright state, it prevents tidal waves, overtopping waves, and floods. The support wall (25) supporting the defensive wall (30) is formed to be curved downward so as to reduce the strength of overtopping waves when they hit it.

The barrier wall (30) of the present invention, like the first embodiment, has a water resistance rubber installed at the part where the barrier wall (30) comes into contact with the door frame (40) during the erection process of the barrier wall (30), so that water resistance is achieved in the erected state of the barrier wall (30).

The present invention installs a floating support (70) connected to the rear middle portion of the defensive wall (30) by a hinge (71) in order to maintain the defensive wall (30) in an erected state when the defensive wall (30) is erected, and the lower side of the floating support (70) moves back and forth along a driving guide (75) installed on the upper portion of a concrete structure (20), and the floating support (70) is supported by a stopper (76) installed at the front end of the driving guide (75) when the erection of the defensive wall (30) is completed, and as a result, the defensive wall (30) is prevented from tipping over due to overtopping, etc., because the driving guide (70) is supported by the stopper (76) in the erected state.

That is, as shown in Fig. 13, during the erection process of the defensive wall (30), the floating support member (70) moves along the driving guide (75) toward the stopper (76) and is supported, thereby completing the erection process, and during the overturning process of the defensive wall (30), it moves along the driving guide (75) toward the defensive wall (30) and overlaps the rear surface of the defensive wall (30) when the defensive wall (30) overturns, thereby completing the overturning process. As a result, the floating support member (70) is erected or laid down during the erection and overturning processes of the defensive wall (30).

And, a support cover (73) is installed in a form that covers the upper side of the above-mentioned fluid support (70), and since the lower side of the support cover (73) is connected to the stopper (76) by a hinge (77), when the fluid support (70) is supported by the stopper (76), the support cover (73) is also raised and covers the fluid support (70), and conversely, when the fluid support (70) is laid down, it is laid down while covering the fluid support (70). Thus, the support cover (73) prevents the exposure of the driving guide (75) and minimizes the exposure of the fluid support (70) to the outside, thereby preventing contamination or damage.

Meanwhile, the defensive wall (30) of the present invention moves along the driving guide (75) when standing up, and when the lower side of the floating support (70) that is erected together with the standing of the defensive wall (30) moves rearward and is supported by the stopper (76), the defensive wall (30) is completely erected. However, in this state, if a strong headwind blows from the rear of the defensive wall (30), the defensive wall (30) is forcibly overturned by the wind pressure, and therefore, in the present invention, a safety pin (80) is installed so that the defensive wall (30) is prevented from being forcibly overturned by the safety pin (80) when it is standing up.

As shown in Fig. 16, several safety pins (80) of the present invention are installed on the upper side of the slide bar (81), and the slide bar (81) is installed to move back and forth in a direction perpendicular to the side of the driving guide (75), but is moved downwardly of the driving guide (75), and the slide bar (81) is moved back and forth by the operation of the hydraulic cylinder (82), and the slide bar (81) is moved while being supported by the movable roller (83) to reduce frictional resistance.

The defensive wall (30) of the present invention is formed by moving the slide bar (81) while supported by the stopper (76) on the lower side of the movable support member (70) so that the movable support member (70) is supported by the stopper (76) while moving along the driving guide (75) during the standing process, thereby forming a pin hole (74) through which the safety pin (80) penetrates the movable support member (70), and when the slide bar (81) is retracted, the safety pin (80) is detached from the pin hole (74) so that the movable support member (70) is laid down, thereby causing the defensive wall (30) to fall over.

The hydraulic cylinder (82) for moving the slide bar (81) of the present invention forward and backward operates in conjunction with the erection of the barrier wall (30). When the barrier wall (30) is completely erected, the hydraulic cylinder (82) is operated to advance the slide bar (81), so that the safety pin (80) is inserted into the pin hole (74) of the floating support member (70), thereby preventing the barrier wall (30) from being forced to fall due to a headwind. When the barrier wall (30) is to fall normally, the slide bar (81) is retracted by the hydraulic cylinder (82) so that the safety pin (80) is removed from the pin hole (74), thereby allowing the barrier wall (30) to fall normally as the floating support member (70) moves.

In the present invention, the hydraulic cylinder (82), the slide bar (81), and the floating roller (83) are installed in a built-in housing (84), and the safety pins (80) are installed in units of 5 to 10 for smooth operation, and the installation of the floating roller (83) is advantageous in assembly and processing compared to the case where a fixed roller is installed, and in cases where precise operation is required, it is appropriate to use a fixed roller instead of using the floating roller (83).

In this second embodiment of the present invention, when the hydraulic cylinder (60) installed in the cylinder room (50) is operated, the barrier wall (30) rotates about the hinge (31) in front of the door frame (40) and is vertically erected on the upper part of the concrete structure (20) or is supported by the support wall (25) and falls over, and in this process, the movable cover (52) covering the cylinder room (50) moves along the cover guide (53) according to the operating angle of the hydraulic cylinder (60) and covers the upper part of the cylinder room (50), and the hydraulic cylinder (60) is guided while the upper movable cover (66) of the cylinder is extrapolated to the lower movable cover (65) of the cylinder and is expanded and contracted, thereby preventing the hydraulic cylinder (60) from being damaged or contaminated by seawater, etc.

The present invention is to prevent damage by erecting the rear side of the defensive wall (30) as a walkway when the defensive wall (30) is overturned, thereby preventing damage by erecting it on top of the concrete structure (20) when a flood, wave overtopping, or tidal wave is expected.

According to the present invention, when looking at the front side of the defensive wall (30) in a fallen state, as shown in FIG. 21, an embankment (10) that is in contact with a river and seawater is visible at the lower side, a concrete structure (20) is visible at the upper side, and a side cylinder cover (55) of a cylinder room (50) is visible, and it can be confirmed that the side of the defensive wall (30) with a safety guard (36) installed at the upper side of the concrete structure (20) is visible, and in this state, walking is performed at the rear side of the defensive wall (30) that raises the upper side, and in this state, maintenance of the hydraulic cylinder (60) installed in the cylinder room (50) is performed by opening the side cylinder cover (55).

And, as shown in Fig. 22, when looking at the front of the defensive wall (30) of the present invention in an erected state, it can be confirmed that the hinge (31) that connects the door frame (40) and the defensive wall (30) and the upper side of the hydraulic cylinder (60) are connected to the front of the defensive wall (30) by a hinge (62), and in this state, when a flood, tidal wave, or overtopping occurs, it is prevented by the defensive wall (30).

In this way, the present invention installs a concrete structure (20) at a height that does not obstruct the view on the embankment (10) of a river or seaside, and installs an erection-type defensive wall (30) on the upper surface of the concrete structure (20), thereby facilitating construction in a narrow space, minimizing the impact on the view and landscape, reducing the economic burden, and improving durability.

10: Embankment 21: Slope
20: Concrete structure 25: Supporting wall
30 : Barrier 31 : Hinge
33: Wave direction change plate 35: Anti-fall support
36,37 : Index rubber 40 : Door frame
50: Cylinder room 51: Inspection cover
52: Fluid cover 55: Front cylinder cover
60: Hydraulic cylinder 65: Cylinder bottom fixing cover
66: Cylinder top fluid cover
70:Floating support 73: Support cover
74 : Pin hole 75 : Driving guide
76 : Stopper 80 : Safety pin
81: Slide bar 82: Hydraulic cylinder
83 : Fluid roller

Claims (7)

A concrete structure (20) with a slope (21) toward the river or seaside is installed on the embankment (10) of a river or seaside and has a certain height so as not to obstruct the view.
A door frame (40) is installed on the upper side of the concrete structure (20) toward the inclined surface (21), and the door frame (40) is fixed to the concrete structure (20) with a reinforcing support (41).
The protective wall (30) is rotated to the upper front of the above door frame (40) and is installed so as to be tilted toward the inclined surface (21) or to be erected perpendicular to the upper side of the concrete structure (20).
A triangular anti-fall support member (35) is installed on the rear of the above-mentioned defensive wall (30) so that it is supported on the upper side of the door frame (40) when the defensive wall (30) is erected.
When the above-mentioned defensive wall (30) is erected, a water-repelling rubber (36)(37) is installed on the lower rear side of the defensive wall (30) that is in close contact with the upper front side of the door frame (40) and on the lower side of the anti-fall support member (35) that is in close contact with the upper side of the door frame (40).
A cylinder room (50) is installed in a form embedded in the inclined surface (21) of the above concrete structure (20), and an inspection cover (51) is installed on the front of the cylinder room (50) so that it is exposed from the inclined surface (21).
A standing wave-breaking and flood prevention wall characterized in that a hydraulic cylinder (60) installed vertically in the cylinder room (50) is hinge-connected to the floor of the cylinder room (50) and the front of the barrier wall (30) so that the barrier wall (30) can be installed upside down or upright. In the first paragraph, a concrete structure (20) is installed at a height of less than 1 m to 1.2 m so as not to obstruct the view, the concrete structure (20) is installed by applying 30% to 60% of the total height of the defensive wall (30), and the concrete structure (20) is formed with a slope (21) of less than 15 degrees to 60 degrees in the direction of the sea of a river or a beach. A standing wave-breaking and flood prevention wall. In the first paragraph, the cylinder room (50) is installed embedded in a concrete structure (20) and has an inspection cover (51) exposed by an inclined surface (21), and a hydraulic cylinder (60) is installed inside the cylinder room (50) with both sides joined by a hinge to stand up, and the lower part of the hydraulic cylinder (60) is covered with a cylinder lower fixed cover (65), while the upper part of the hydraulic cylinder (60) is covered with a cylinder upper floating cover (66), and the hydraulic cylinder (60) is expanded in a state where the cylinder upper floating cover (66) is extrapolated to the cylinder lower fixed cover (65) according to the operation of the hydraulic cylinder (60), and the floating cover (52) covering the upper part of the cylinder room (50) moves forward and backward while being fitted to a cover guide (53) installed on the upper side of the cylinder room (50) according to the operation angle of the hydraulic cylinder (60), and during the erection process of the barrier (30), An erecting wave-break and flood-prevention wall characterized by blocking the upper part of a cylinder room (50). In the first paragraph, a standing wave-breaking and flood prevention wall characterized in that a wave direction conversion plate (33) is installed horizontally on the front side of the barrier (30), and the wave direction conversion plate (33) is installed at an angle of 20 to 80 degrees to convert the direction of a wave hitting the barrier (30) and reduce the wave-breaking force. A concrete structure (20) with a certain height is installed on the embankment (10) of a river or seaside so as not to obstruct the view.
A door frame (40) is installed in the above concrete structure (20), and the door frame (40) is fixed to a reinforcing support (41) inside the concrete structure (20).
The protective wall (30) is rotated toward the upper front of the above door frame (40) and installed so as to be horizontally or perpendicularly installed to the upper side of the concrete structure (20).
On the rear of the above-mentioned defensive wall (30), a movable support (70) is installed so as to be rotatable, which moves along a driving guide (75) installed horizontally on a concrete structure (20) and is supported by a stopper (76) to erect the defensive wall (30).
The upper part of the above-mentioned floating support (70) is covered with a support cover (73), and the rear of the support cover (73) is rotatably installed on a stopper (76).
The slide bar (81) is installed in a direction perpendicular to the side of the above driving guide (75), and the slide bar (81) is installed to be moved back and forth by a hydraulic cylinder (82) while being supported by a fluid roller (83).
A safety pin (80) is installed on the upper side of the slide bar (81) to be inserted into the pin hole (74) formed on the lower side of the floating support (70), so that when the floating support (70) is supported by the stopper (76) and the barrier wall (30) is erected, the slide bar (81) is moved so that the safety pin (80) is inserted into the pin hole (74), and when the slide bar (81) is retracted, the safety pin (80) is detached from the pin hole (74) so that the floating support (70) falls over.
In the above concrete structure (20), a cylinder room (50) is installed in which a hydraulic cylinder (60) for lifting or erecting a defensive wall (30) is installed, and a front cylinder cover (55) is installed so that the front of the cylinder room (50) is exposed to the front of the concrete structure (20).
A hydraulic cylinder (60) installed vertically in the cylinder room (50) is hinged to the floor of the cylinder room (50) and the front of the defensive wall (30) to install the defensive wall (30) so that it can be turned over or erected.
A standing wave-breaking and flood-prevention wall characterized in that the barrier wall (30) is formed by being supported horizontally on a concrete structure (20) by installing a support wall (25) that is supported by a hydraulic cylinder (60). In the fifth paragraph, a concrete structure (20) is installed at a height of less than 1 m to 1.2 m so as not to obstruct the view, the concrete structure (20) is installed by applying 30% to 60% of the total height of the defensive wall (30), and a support wall (25) that horizontally supports the defensive wall (30) is installed on the concrete structure (20), characterized in that it is an erecting wave-breaking and flood-prevention wall. In the fifth paragraph, the cylinder room (50) is installed embedded in the concrete structure (20), and has a front cylinder cover (55) exposed to the front of the concrete structure (20), and a hydraulic cylinder (60) is installed inside the cylinder room (50) with both sides joined by hinges to stand up, and the lower end of the hydraulic cylinder (60) is covered with a cylinder lower fixed cover (65), while the upper end of the hydraulic cylinder (60) is covered with a cylinder upper floating cover (66), and the hydraulic cylinder (60) is expanded in a state where the cylinder upper floating cover (66) is extrapolated to the cylinder lower fixed cover (65) according to the operation of the hydraulic cylinder (60), and the floating cover (52) covering the upper end of the cylinder room (50) is exposed to the upper end of the concrete structure (20), and is installed in a cover guide (53) installed on the upper end of the cylinder room (50) according to the operation angle of the hydraulic cylinder (60). An erecting wave-breaking and flood-prevention wall characterized by moving forward and backward while being inserted and blocking the upper part of the cylinder room (50) during the erection process of the defensive wall (30).