KR101842084B1 - structure of retaining wall - Google Patents

Abstract

The present invention relates to a retaining wall construction structure of a novel structure which enables a user to accurately identify a distance that the retaining wall is pushed out by soil pressure. In the retaining wall construction structure according to the present invention, a fixing groove (22), and front and rear recess grooves (23, 24), extending forward and backward from the fixing groove (22), are formed in the upper surface of a reinforcing block (20) to be recessed downwardly, and a display means (70) is provided on the reinforcing block (20) to display a distance from which the reinforcing block (20) is pushed out when the reinforcing block (20) is pushed out forwardly by soil pressure. When the reinforcing block (20) is pushed out forwardly by soil pressure, the display means (70) displays a distance that the reinforcing block (20) is pushed out forwardly, thereby allowing a user to identify an exact distance that the reinforcing block (20) is pushed out forwardly by soil pressure.

Description

Structure of retaining wall

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a retaining wall construction structure of a new structure capable of accurately confirming the distance the retaining wall is pushed by the earth pressure.

Generally, a retaining wall is installed on the incision surface to prevent the loss or collapse of the earth.

These retaining walls are formed by arranging the reinforcing blocks, which are produced by molding the concrete into a certain shape, on the incision surface so as to be stacked in the vertical direction.

However, in the case of such a retaining wall, the middle portion of the retaining wall is pushed forward by the earth pressure generated on the cut surface when the time elapses after the construction, and if it is severe, the retaining wall may be collapsed.

Therefore, when the middle portion of the retaining wall is pushed forward, it is necessary to accurately grasp the extent to which each reinforcing block has been pushed forward. However, the conventional retaining wall has a problem in that it is difficult to accurately grasp the extent to which the reinforcing block is pushed forward .

However, such a reinforcing block is made of a concrete material, and there is a problem that the retaining wall constructed by laminating such a reinforcing block is not compatible with the surrounding environment.

Therefore, recently, a vegetation part for planting is formed at the front end of the reinforcing block, and plants of various kinds are planted in the vegetation part, so that the finished retaining wall can be matched with the surrounding environment.

In addition, such a retaining wall must be managed such as continuously supplying water to the vegetated vegetation in the vegetation part of the reinforcing block. Such a retaining wall has a problem that it is difficult to manage the vegetated plant in the vegetation part of the reinforcing block.

Therefore, there is a need for a new method to solve such a problem.

On the other hand, in the case of such a cut surface, groundwater or rainwater is discharged through the incision surface.

10-1235826,

SUMMARY OF THE INVENTION It is an object of the present invention to provide a new construction for a retaining wall that can accurately confirm the distance the retaining wall is pushed by the earth pressure.

In order to accomplish the above object, the present invention is characterized in that a plurality of reinforcing blocks (20) are laminated on a cut surface (1) whose upper end is inclined rearwardly, and the reinforcing block (20) Wherein the vegetation part (21) is formed so as to pass through the upper and lower surfaces and the rear end part is stacked in the vertical direction so as to be in close contact with the incision surface (1), wherein the upper surface of the reinforcing block (20) The front and rear recessed grooves 23 and 24 extending in the front and rear direction in the fixing groove 22 are recessed downwardly and the reinforcing block 20 is coupled to the reinforcing block 20, Further comprising display means (70) for displaying the distance that the reinforcing block (20) is pushed out when pushed out, wherein the display means (70) is formed in a shape corresponding to the fixing groove (22) A case 71 having through holes 71a and 71b formed therein, A rotary gear 72 rotatably coupled to the rotary shaft 72a and a bar gear 73 extending forward and rearward and having gear teeth 73a meshed with a peripheral surface of the rotary gear 72 at its front end And a rear end portion of the connecting bar 73 extends rearward of the case 71 through the rear through hole 71b and is slidably inserted into the rear recess groove 24 in the forward and backward directions, And a gear tooth 74a is formed at the rear end of the rotary gear 72 to engage with the other circumferential surface of the rotary gear 72. The front end of the gear tooth 74a is slidable in the front concave groove 23 through the front through hole 71a An anchor member 74 fixed to be embedded in the incision surface 1 and connected to the rear end of the connecting bar 73 through a wire 75a, (75), characterized in that the retaining wall construction It is a ball.

According to another aspect of the present invention, an inflow port 11, which is formed in a cylindrical shape having a water storage space therein and is provided at a front lower side of the incision surface 1 and in which water discharged from the incision surface 1 flows, (10) in which water discharged from the incision surface (1) is formed so as to be stored inside the inlet (11) and the reinforcing block (20) is stacked on the upper surface, A plurality of drainage holes 31 are formed in the surface of the reinforcing block 20 so as to penetrate the vegetation portion 21 of the reinforcing block 20 and a connection pipe 30 connecting the storage tank 10 and the water supply pipe 30, A water supply pump 50 connected to the connection pipe 40 to supply the water stored in the water storage tank 10 to the water supply pipe 30 and a water supply pump 50 connected to the vegetation part 21 A humidity sensor 60 provided in the vegetation part 21 for measuring the humidity of the soil filled in the vegetation part 21, (10) or a reinforcing block (20) and connected to the solar generator (101) to output electricity when the sunlight is irradiated. The solar generator (101) (100) for supplying electricity to the water supply pump (50), and a control unit for receiving a signal from the humidity measurement sensor (60) and operating the water supply pump (50) (110) monitors the signal of the humidity measurement sensor (60) and controls the humidity of the soil filled in the vegetation part (21) The water pump 50 is operated so that the water stored in the water storage tank 10 is supplied to the soil filled in the vegetation part 21 through the connection pipe 40 and the water supply pipe 30 A retaining wall construction structure is provided.

According to another aspect of the present invention, there is provided a display device including: a protrusion distance measurement unit 80 provided in the display unit 70 for measuring a distance that the reinforcing block 20 is protruded forward by earth pressure; The protruding distance measuring means 80 includes an angle sensor provided on the rotating shaft 72a and measuring the rotational angle of the rotating gear 72, The control means 110 receives the signal of the protrusion distance measuring means 80 and turns on the lamp 90 when the reinforcing block 20 is pushed forward beyond a previously inputted reference distance A retaining wall construction structure is provided.

According to the retaining wall construction of the present invention, the upper surface of the reinforcing block 20 is provided with a fixing groove 22 and front and rear recessed grooves 23 and 24 extending forward and backward from the fixing groove 22, And the reinforcing block 20 is provided with a display means 70 for indicating the distance the reinforcing block 20 is pushed out when the reinforcing block 20 is pushed forward by the earth pressure so as to be reinforced by the earth pressure When the block 20 is pushed forward, the display means 70 displays the distance the reinforcing block 20 is pushed forward, so that the distance that the reinforcing block 20 is pushed forward by the earth pressure can be accurately confirmed There are advantages to be able to.

1 is a side sectional view showing a retaining wall construction according to the present invention,
FIG. 2 is an enlarged view showing a main part of a retaining wall construction according to the present invention,
3 is a plan view showing a reinforcing block of a retaining wall construction according to the present invention,
FIG. 4 is a side cross-sectional view taken along line AA of FIG. 3,
5 is a circuit configuration diagram of a retaining wall construction according to the present invention,
Figs. 6 and 7 are reference views illustrating the operation of the retaining wall construction according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 to 7 illustrate a retaining wall construction according to the present invention. The retaining wall construction is the same as that of the conventional art in which a plurality of reinforcing blocks 20 are stacked on a cut surface 1 whose upper end is inclined rearward.

At this time, the reinforcing block 20 is vertically stacked so that the vegetation part 21 through which the soil is filled passes through the upper and lower surfaces of the reinforcing block 20, and the rear end thereof is in close contact with the cut surface 1.

Therefore, plants may be planted in the soil filled in the vegetation part 21 after filling the vegetation part 21 of the reinforcing block 20 with soil.

According to the present invention, an inlet 11 is formed in the front lower side of the incision surface 1, and an inlet 11 through which water discharged from the incision surface 1 flows is formed (10) in which the water discharged from the incision surface (1) is stored inside the inlet (11) and the reinforcing block (20) is stacked on the upper surface, A connection pipe 40 connecting the water storage pipe 10 and the water supply pipe 30 and connected to the connection pipe 40 so as to pass through the vegetation part 21 of the block 20; A water supply pump 50 for supplying water stored in the water storage tank 10 to the water supply pipe 30 and a water supply pump 50 for supplying water stored in the water storage tank 10 to the water supply pipe 30, A humidity sensor 60 for measuring the humidity of the soil; and a humidity sensor 60 for measuring the humidity of the soil, wherein the reinforcing block 20 is coupled to the reinforcing block 20, A display means (70) for displaying the distance the reinforcing block (20) is pushed out when the reinforcing block (20) is pushed out into the room and a distance measuring means A lamp 90 provided on a front surface of the reinforcing block 20, a power generating means 100 provided in the storage tank 10, a humidity sensor 60, The control unit 110 further receives a signal from the protrusion distance measuring unit 80 and controls the operation of the water supply pump 50 and the lamp 90.

1 to 3, the reinforcing block 20 includes a fixing groove 22 on an upper surface thereof, front and rear recessed grooves 23 extending in the front and rear direction in the fixing groove 22, And 24 are concave downward.

For this, the vegetation part 21 is formed at the center of the reinforcing block 20, and the fixing groove 22 and the front and rear recessed grooves 23 and 24 are formed so as not to interfere with the vegetation part 21 Is formed on one side of the upper surface of the reinforcing block (20).

At this time, the front concave groove 23 is formed deeper than the rear concave groove 24.

As shown in FIG. 1, the reservoir 10 is formed in a rectangular box shape having a longer length in the front-rear direction and the lateral direction than the reinforcing block 20, so that the rear end portion is embedded in the cut- And the inflow port 11 is formed on the upper side of the rear side so that rainwater or groundwater discharged to the cut surface 1 is stored inside the inflow port 11. [

At this time, a filter member 12 is provided in the inlet 11 so that foreign matter other than water, that is, soil released from the incision surface 1, flows into the inside of the storage tank 10 through the inlet 11 Do not enter.

The water supply pipe 30 is made of a synthetic resin material having a closed bottom and has a plurality of drain holes 31 formed on the circumference of the water supply pipe 30. The water supply pipe 30 is filled with a plurality of mutually stacked reinforcing blocks 20, And is arranged to penetrate the soil in the vertical direction.

The connection pipe (40) is made of a flexible synthetic resin material.

6, the water supply pump 50 is provided at an intermediate portion of the connection pipe 40 and is operated by a power source supplied by the power generation means 100 to supply the water to the water storage tank 10, And supplies the water to the water supply pipe (30).

At this time, the water supplied to the water supply pipe (30) is supplied to the soil filled in the vegetation part (21) through the drain hole (31) of the water supply pipe (30), thereby increasing the humidity of the soil.

2 and 3, the humidity measurement sensor 60 is fixed to the inner surface of the vegetation part 21 and configured to measure the humidity of the soil filled in the vegetation part 21 do.

As described above, various types of humidity sensor 60 for measuring the humidity of the object have been developed and widely used, and a detailed description thereof will be omitted.

3 and 4, the display means 70 is formed in a shape corresponding to the fixing groove 22 and includes a case 71 having front and rear through holes 71a and 71b formed on the front and rear surfaces thereof, A rotary gear 72 rotatably coupled to a rotary shaft 72a provided inside the case 71 and a bar extending in the fore and aft direction and having a front end portion formed at one side of the rotary gear 72 And a rear end portion of the connecting bar 71 is extended to the rear of the case 71 through the rear through hole 71b so as to be slidably inserted into the rear recess groove 24 in the front- And a gear tooth 74a is formed at the rear end of the gear tooth 74a so as to engage with the other circumferential surface of the rotary gear 72. The front end of the gear tooth 74a is connected to the front through hole 71a A display bar 74 slidably inserted into the front concave groove 23, Fixed so embedded in the surface (1) and consists of an anchor member 75 which is connected to the rear end of the connecting bar 73 through a wire (75a).

The case 71 is made of a synthetic resin material having high strength.

The rotation shaft 72a is fixed to the inside of the case 71 so as to extend laterally and the rotation gear 72 is rotatably coupled to the outside of the middle portion of the rotation shaft 72a.

The connecting bar 73 is sufficiently long in the front and rear direction so as to extend rearward of the reinforcing block 20 through the rear concave groove 24 and has a ring And the gear teeth 73a at the front end portion are engaged with the upper circumferential surface of the rotary gear 72. [

The indicator bar 74 has a scale 74b at the front end thereof and a gear tooth 74a at the rear end thereof meshed with the lower circumferential surface of the rotary gear 72. The front end of the display bar 74 And is positioned so as to be flush with the front surface.

The anchor member 75 is formed in a wedge shape and is fixed so as not to fall forward when it is embedded in the incision surface 1. [

The wire 75a is made of a synthetic resin material having high strength.

At this time, the anchor member 75 is sufficiently deeply embedded in the incision surface 1 and flows into the front surface of the incision surface 1 to push the reinforcing block 20 forward, as described later, The position of the anchor member 75 is not changed.

The display means 70 is not provided in all the reinforcing blocks 20 provided on the retaining wall but is selectively provided in several reinforcing blocks 20 required to be measured.

7, when the reinforcing block 20 is pushed forward by the earth pressure generated on the incision surface 1, the connecting bar 73 is moved forward by the anchor member 75 Only the case 71 is pushed forward without being pushed, whereby an effect of pulling the connecting bar 73 backward is generated, whereby the rotating gear 72 is rotated clockwise.

When the rotary gear 72 is rotated in the clockwise direction, the display bar 74 is pushed forward and protrudes forward of the reinforcing block 20.

The distance that the display bar 74 protrudes forward of the reinforcing block 20 is equal to the distance that the reinforcing block 20 is pushed forward due to the earth pressure so that the manager projects the reinforcing block 20 in front of the reinforcing block 20 The distance that the reinforcing block 20 is pushed forward due to the earth pressure can be accurately confirmed by reading the scale 74b of the display bar 74. [

As shown in FIG. 4, the protruding distance measuring means 80 uses an angle sensor provided on the rotating shaft 72a to measure the rotating angle of the rotating gear 72. As shown in FIG.

That is, as shown in FIG. 7, when the reinforcing block 20 is pushed forward by the earth pressure, the rotating gear 72 is rotated and the display bar 74 is pushed forward.

Since the diameter of the rotation gear 72 is known, the rotation angle of the rotation gear 72 is measured using the protrusion distance measuring means 80, and the measured rotation angle and the rotation angle of the rotation gear 72 The distance that the display bar 74 is pushed forward, that is, the distance that the reinforcing block 20 protrudes forward and is measured can be measured.

The lamp 90 uses an LED lamp and is provided on a front upper surface of the reinforcing block 20.

The power generating means 100 includes a solar generator 101 provided on one side of the reinforcing block 20 and outputting electricity when sunlight is irradiated to the solar generator 100. The solar generator 100 is connected to the solar generator 101, And a rechargeable battery 102 for storing the electricity output from the battery 101.

When the humidity of the soil filled in the vegetation part 21 is lower than the reference humidity previously inputted, the control part 110 receives the signal of the humidity measurement sensor 60, When the water supply pump 50 is driven and the signal of the protrusion distance measuring means 80 is received and the reinforcing block 20 is pushed forward beyond the previously inputted reference distance, the lamp 90 is turned on .

At this time, the reference humidity is set to be slightly lower than the humidity suitable for growing plants planted in the vegetation part 21, and the reference distance is set to be slightly shorter than a distance at which the safety of the retaining wall may cause a problem.

Therefore, if the humidity of the soil filled in the vegetation part 21 becomes lower than the reference humidity, the control unit 110 confirms the humidity through the humidity measuring unit, and then the water supply pump 50 So that the water stored in the water storage tank 10 is supplied to the soil filled in the vegetation part 21 through the connection pipe 40 and the water supply pipe 30 so that the humidity of the soil is reduced to the reference humidity .

8, when the reinforcing block 20 is pushed forward by the earth pressure on the cut surface 1, the control means 110 outputs a signal of the projecting distance measuring means 80 And when the reinforcing block 20 is pushed forward beyond the previously inputted reference distance, the lamp 90 is turned on so that the manager can check it quickly.

According to the above-described retaining wall construction, the upper surface of the reinforcing block 20 is provided with a fixing groove 22 and front and rear recessed grooves 23 and 24 extending forward and backward from the fixing groove 22, And the reinforcing block 20 is provided with a display means 70 for indicating the distance the reinforcing block 20 is pushed out when the reinforcing block 20 is pushed forward by the earth pressure, A case 71 having front and rear through holes 71a and 71b formed on the front and rear surfaces thereof and a rotary shaft 72a provided inside the case 71. The case 71 is formed in a shape corresponding to the fixing groove 22, And a gear tooth 73a engaged with one circumferential surface of the rotary gear 72 is formed at the front end of the rotary gear 72. The rear end portion of the gear 73a is connected to the rear Through the through hole (71b) to the rear recessed groove (24) And a gear tooth 74a meshing with the other circumferential surface of the rotary gear 72 is formed at the rear end of the connecting bar 73. The front end A display bar 74 slidably inserted into the front concave groove 23 through the front through hole 71a and having a scale 74b at a front end thereof and a display bar 74 fixed to be embedded in the cut face 1, And an anchor member 75 connected to the rear end of the connecting bar 73 through a connecting hole 75a.

Therefore, when the reinforcing block 20 is pushed forward by the earth pressure, the display bar 74 protrudes forward of the reinforcing block 20 to display the distance that the reinforcing block 20 is pushed forward, It is possible to accurately check the distance that the reinforcing block 20 is pushed forward.

An inlet 11 is formed on the upper surface of the incision surface 1 so as to receive the water discharged from the incision surface 1 to form the incision surface 1, (10) in which water discharged from the water inlet (1) is stored inside the inlet (11) and the reinforcing block (20) is stacked on the upper surface thereof, 31), a water supply pipe (30) arranged to penetrate the vegetation part (21) of the reinforcing block (20), a connection pipe (40) connecting the water storage pipe (10) and the water supply pipe (30) A water supply pump 50 connected to the connection pipe 40 to supply the water stored in the water storage tank 10 to the water supply pipe 30 and a water supply pump 50 provided in the vegetation part 21 of the reinforcing block 20, A humidity sensor 60 for measuring the humidity of the soil filled in the storage unit 21 and a humidity sensor 60 for measuring the humidity of the soil filled in the storage tank 10 or the reinforcing block 2 And a battery 102 connected to the photovoltaic generator 101 and storing electricity output from the photovoltaic generator 101. The photovoltaic power generator 101 is provided on one upper surface of the photovoltaic power generator 101, (110) configured to receive signals from the humidity measurement sensor (60) and to control the operation of the feed pump (50), the control means When the humidity of the soil filled in the vegetation part 21 drops below a previously inputted reference humidity, the control unit 110 operates the water supply pump 50 so that the water stored in the water storage tank 10, Water is supplied to the soil filled in the vegetation part (21) through the connection pipe (40) and the water supply pipe (30).

Therefore, even if the water is not separately managed, water is continuously supplied to the soil filled in the vegetation part 21, so that maintenance is very easy.

The protruding distance measuring means 80 provided in the display means 70 and measuring the distance of the reinforcing block 20 protruded forward by the earth pressure and the protruding distance measuring means 80 are provided on the front surface of the reinforcing block 20, Wherein the protruding distance measuring means 80 includes an angle sensor provided on the rotary shaft 72a and measuring the rotation angle of the rotary gear 72, And receives the signal of the protrusion distance measuring means 80 and turns on the lamp 90 when the reinforcing block 20 is pushed forward beyond a previously inputted reference distance.

Therefore, when the reinforcing block 20 is pushed forward so as to cause a problem in safety of the retaining wall, it is possible to easily confirm the scale 74b without checking the scale bar 74b of the display bar 74, There is an advantage to be able to repair.

10. Reservoir 20. Reinforcement block
30. Water supply pipe 40. Connection pipe
50. Feed pump 60. Humidity measuring means
70. Display means 80. Projection distance measuring means
90. Generation means 110. Control means

Claims (3)

And a plurality of reinforcing blocks (20) stacked on the cut surface (1)
The reinforcing block (20) is structured such that a vegetation part (21) filled with soil is formed at the front end part so as to penetrate the upper and lower surfaces, and the rear end part is vertically stacked so as to be in close contact with the cut surface (1)
On the upper surface of the reinforcing block 20, a fixing groove 22 and front and rear recessed grooves 23 and 24 extending forward and backward from the fixing groove 22 are recessed downward,
Further comprising display means (70) coupled to the reinforcing block (20) for indicating the distance the reinforcing block (20) is pushed out when the reinforcing block (20) is pushed forward by the earth pressure,
The display means (70)
A case 71 having front and rear through holes 71a and 71b formed in a shape corresponding to the fixing groove 22,
A rotary gear 72 rotatably coupled to a rotary shaft 72a provided in the case 71,
A gear tooth 73a engaging with one peripheral surface of the rotary gear 72 is formed at a front end portion thereof and a rear end portion of the gear tooth 73a is engaged with a rearward portion of the case 71 through the rear through hole 71b. A connecting bar 73 extending in the front and rear direction so as to be slidably inserted into the rear concave groove 24,
And a gear tooth 74a engaging with the other peripheral surface of the rotary gear 72 is formed at the rear end thereof and a front end portion thereof is formed in the front concave groove 71a through the front through hole 71a, 23, a display bar 74 having a scale 74b at the front end thereof,
And an anchor member (75) fixed to be embedded in the incision surface (1) and connected to a rear end of the connection bar (73) through a wire (75a).
The method according to claim 1,
And an inlet 11 through which the water discharged from the incision surface 1 flows is formed on the upper surface of the incision surface 1 to form the incision surface 1, (10) configured to store water discharged from the water inlet (11) through the inlet (11) and having the reinforcing block (20) stacked on the upper surface thereof,
A water supply pipe (30) extending in the vertical direction and having a plurality of drain holes (31) formed on the peripheral surface thereof and arranged to penetrate the vegetation part (21) of the reinforcing block (20)
A connection pipe (40) connecting the storage tank (10) and the water supply pipe (30)
A water supply pump (50) connected to the connection pipe (40) for supplying water stored in the water storage tank (10) to the water supply pipe (30)
A humidity measuring sensor 60 provided in the vegetation part 21 of the reinforcing block 20 for measuring the humidity of the soil filled in the vegetation part 21,
A photovoltaic generator 101 provided on an upper surface of one side of the storage tank 10 or the reinforcing block 20 for outputting electricity when sunlight is irradiated, a photovoltaic generator 101 connected to the photovoltaic generator 101, (100) for supplying electricity to the water supply pump (50), and a rechargeable battery (102) for storing electricity output from the water supply pump (50)
Further comprising control means (110) configured to receive a signal of the humidity measurement sensor (60) and to control the operation of the feed pump (50)
The control unit 110 monitors the signal of the humidity measurement sensor 60 and operates the water supply pump 50 when the humidity of the soil filled in the vegetation unit 21 falls below the pre-input reference humidity Wherein water stored in the water storage tank (10) is supplied to the soil filled in the vegetation part (21) through the connection pipe (40) and the water supply pipe (30).
3. The method of claim 2,
A protruding distance measuring means 80 provided in the display means 70 for measuring the distance of the reinforcing block 20 projected forward by the earth pressure,
Further comprising a ramp (90) provided on a front surface of the reinforcing block (20)
The protruding distance measuring means 80 uses an angle sensor provided on the rotary shaft 72a to measure the rotation angle of the rotary gear 72,
The control means 110 receives the signal of the projecting distance measuring means 80 and turns on the lamp 90 when the reinforcing block 20 is pushed forward beyond a previously inputted reference distance .

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