KR101678127B1 - Block for engineering works - Google Patents

Abstract

The present invention makes it possible to provide convenience of construction by preventing the need for backfilling construction by integrating the vegetation surface and the drainage site, and at the same time, the hydraulic pressure of the soil located inside or behind the block can be lowered to provide structural safety, The present invention relates to a civil engineering block capable of being installed on a building.
The present invention is characterized in that a planting portion in which a plurality of planting holes penetrating downward in an anteroposterior direction are formed and plants are planted thereon; A reinforcing filler filling the reinforcing soil to reinforce the supporting force of the structure so as to form the vegetation base of plants planted in the planting hole; The reinforcing soil filled in the reinforcing soil filling hole or the drain for discharging the water of the soil located on the rear surface in a downward direction is sequentially formed from the potential, .

Description

Block for engineering works

The present invention relates to a civil engineering block, and more particularly, to a construction block, and more particularly, to a construction block in which a vegetation surface and a drainage section are integrated to prevent the need for backfilling, thereby reducing the water pressure of the soil located inside or behind the block, So that a stable curved surface construction is made possible.

As we all know, in Korea, the importance of soil stabilization and slope protection is of paramount importance in constructing retaining walls such as slopes of roads and railways, slopes of park areas, river banks, and coastal roads, Structures, concrete blocks or retaining walls closed with concrete panels are the mainstream.

The conventional retaining wall, which is finished with the entire concrete wall as above, has a gray light appearance which is not in harmony with the surrounding natural environment, which greatly damages the scenery of the city and is heterogeneous from the original natural ecosystem, It is becoming a factor to deteriorate natural ecological environment such as small animals.

In addition, the drainage holes are drilled for the front wall drainage with concrete surface, and backfill works are carried out with gravel etc. However, there is a risk of collapse due to hydraulic pressure and earth pressure because the drainage can not be performed smoothly. There was a great difficulty.

In view of this, in Korean Patent No. 10-0934098, a retaining wall block having a planting hole formed to allow upper and lower portions to pass therethrough is constructed, and these retaining wall blocks are stacked in a zigzag fashion, and the soil is filled in the planting hole, The plant is planted in the soil of.

However, since the retaining wall blocks such as the domestic registered patent No. 10-0934098 are stacked in a zigzag form, the exposed areas are very narrow and the vegetation can not be smoothly performed, , And the wide front surface of the retaining wall block can not be exposed to the outside.

In addition, when the retaining wall block according to the Korean Patent No. 10-0934098 is installed, the water contained in the soil can be drained smoothly, so that the retaining wall block is seated so as to lower the hydraulic pressure and the earth pressure of the soil. If the backfill is not properly carried out, there is a risk of subsidence, and the water pressure and the earth pressure of the soil placed on the rear wall of the retaining wall block In addition, there is a drawback in that it requires a separate aggregate necessary for backfill construction, so that it takes a lot of space in construction, and the aggregate must be moved from the place of work to the construction site. .

The present invention has been proposed in view of this point and it is aimed at making the convenience of construction by making the vegetation surface and drainage site unite so as to prevent the need for backfilling and to reduce the hydraulic pressure of the soil located inside or behind the block, And to provide a civil engineering block that enables a stable curved surface construction.

In order to solve the above-mentioned problems, the present invention provides a food processing apparatus comprising: a planting portion formed at an electric potential and formed with a plurality of planting holes penetrating downwardly in an anteroposterior direction,
A reinforcing soil filling ball which is formed in succession to the planting portion and is filled with reinforcing soil to reinforce the supporting force of the structure and form the vegetation foundation of plants planted in the planting hole;
The reinforcing soil filling hole has a structure formed in succession to the reinforcing soil filling hole and having a strength capable of maintaining its shape and allowing water to pass therethrough. Thus, the water in the reinforcing soil filled in the reinforcing- Wherein the drainage unit is formed integrally so as to be sequentially positioned from the potential;
Wherein the drainage portion includes a first bulkhead formed in a portion contacting the end portion of the reinforcing filler and formed with a plurality of through holes and a second bulkhead formed at a rear end of the ground block in a state in which a plurality of through holes are formed;
Wherein a coupling protrusion is formed at a lower portion of the planting portion and an arc-shaped coupling groove for fitting the coupling protrusion is formed at an upper portion of the planting portion,
The bottom part between the first and second partitions is provided with a closed surface having a plurality of drainage holes. The space defined by the first partition, the second partition, the side walls of the civil block, The gravel being configured to be filled;
Wherein the coupling protrusion is formed at a position where the coupling protrusion is formed in the upper part of the planting hole and the coupling protrusion is protruded downward at the rear end of the upper half-coupling part;
Wherein a bottom half type recess corresponding to a lower half of the planting hole is formed in a downwardly inclined manner at a joint groove forming position of the planting part, the arched groove is formed at a rear end of the bottom half type work, And the upper and lower halves are combined to form a complete planting hole.

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In the civil engineering block according to the present invention, since the planting portion and the drainage portion are integrally formed, if the slurry is installed on a slope or the like, the drainage can be smoothly performed without a separate backfilling work on the rear surface of the civil engineering block.

Also, in the construction of the drainage part, the general concrete and the porous concrete can be formed at one time, so that the civil engineering block can be manufactured easily, and two partition walls are formed between the rear walls of the civil engineering block, Even if the drainage part is filled up, it can be transported to the construction site by filling the gravel to the civil block before the delivery, or it can be transported to the construction site by making the gravel bag, so construction can be carried out directly without transporting the aggregate or backfilling the aggregate. It is very easy to construct, and there is also an advantage that a separate aggregate space is not required at the construction site.

In the state where construction of the structure is completed, the moisture of the soil placed on the backside of the reinforcing soil filled in the reinforcing soil filling ball or the soil block located on the back of the civil engineering block can be drained downwardly through the drainage part, so that the hydraulic pressure of the whole soil is reduced, .

In addition, when plants are planted in a plurality of downward sloping planting holes formed in the planting portion, the roots of the plant can naturally grow more smoothly by lowering the roots in the soil filled in the reinforcing soil filling ball in the middle portion of the civil block. , It is possible to continuously grow after inserting into the soil, so that there is an advantage that the green state can be continuously maintained on the entire surface of the civil engineering block.

In addition, since the plant can be planted in an oblique direction through a planting hole having a downward inclined shape, the planting material can be facilitated and the planting hole can be inclined downward. Therefore, the soil filled in the reinforcing soil filling ball can be prevented from coming out through the planting hole And the vegetation environment can be maintained smoothly. Also, since the civil engineering block front is made flat after the construction, there is an advantage that the appearance can be improved.

1 is a perspective view of a civil engineering block according to the present invention;
2 is a sectional view of a civil engineering block according to the present invention.
3 is a sectional view of a civil engineering block according to the present invention in a construction state.
4 is a front view of the construction block of the civil engineering block according to the present invention.
5 is an explanatory view of a curved surface construction of a civil engineering block according to the present invention.
6 is a sectional view of a civil engineering block according to another embodiment of the present invention.
7 is a sectional view of the construction block according to Fig. 6 in a construction state.
8 is a sectional view of a civil engineering block according to another embodiment of the present invention.
Fig. 9 is a sectional view of the civil engineering block according to Fig. 8 in a construction state. Fig.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the attached drawings.

As shown in the drawing, a civil engineering block according to the present invention includes a plurality of planting holes 11 formed therein, a planting portion 10 on which plants are planted, and a strength capable of maintaining the shape And the drainage part 20 is connected to the drainage part 20 and the drainage part 20 is connected to the drainage part 20 through the drainage part 20 and the drainage part 20, A reinforcing soil filling hole 30 is provided between the planting portion 10 and the drainage portion 20 to reinforce the supporting force of the structure and fill the reinforcing soil so as to form vegetation base of plants planted in the planting hole 11, Is formed.

The drainage part 20 is made of a porous concrete material and is formed integrally with the planting part 10 of the general concrete material and the side wall 31 forming the reinforcing soil filling hole 30 at the same time.

The porous concrete constituting the drainage section 20 prevents the large discharge roots of the plant from being excessively large so that the discharge passage of the water is prevented from being too large and the root roots extend through the drainage section 20 and have a certain water holding capacity, In the case where the water contained in the soil on the back side of the reinforced soil or the block of the civil engineering block is drained and water is insufficient as in the case of the dry season, water is gradually supplied to the reinforced soil to continuously grow the plant. desirable.

In addition, a plurality of drain holes 21 communicating with each other in the vertical direction may be formed in the drainage section 20 so that the drainage can be smoothly performed. The porous concrete constituting the drainage section 20 may be porous Concrete can be applied.

The planting part 10 is made of a non-porous general concrete material forming a front surface of the block. In the planting part 10, a plurality of planting holes 11 penetrating downward in a forward and backward direction are formed, . The shape of the planting hole 11 may be various shapes such as a circular shape and a square shape and the planting angle of the planting hole 11 may be variously changed depending on the thickness of the planting material 10, .

A coupling protrusion 41 is formed in the lower part of the planting part 10 and an arc-shaped coupling groove 42 is formed in the upper part of the planting part 10 to fit the coupling protrusion 41, .

The engaging protrusions 41 and the engaging grooves 42 are formed on the entire surface of the planting portion 10 so that the engaging protrusions 41 and the engaging grooves 42 can be engaged with the engaging grooves 42 or the engaging protrusions 41 of other blocks zigzag- Respectively.

Since the planting hole 11 is formed to be inclined downwardly, it is necessary to provide a specific mold to form the planting part 10 in the middle of the planting part 10, and it takes a lot of time to perform a precise work in case of demolding. The upper half-working hole 11a corresponding to the upper half of the planting hole 11 is formed to be downwardly inclined at the coupling protrusion forming position of the planting hole 10 in consideration of this, The coupling protrusion 41 is formed to protrude downward in the rear end portion and the lower half-revolving hole 11b corresponding to the lower half of the planting hole 11 is inclined downward at the coupling groove forming position of the planting portion 10 Shaped engaging groove 42 is formed at the rear end of the lower half-finished work 11b so that the engaging projection 41 is engaged with the engaging groove 42 and the upper half-working hole 11a and the lower half- ) Are combined to form a complete The preferred are configured to fulfill a planting hole 11.
In this case, it is obvious that the planting hole 11 should not be blocked so that the vegetation can be smoothly planted after the planting of the plant. Thus, as shown in the drawing, the length of the coupling protrusion 41 is the same as the length of the lower half- It is obvious that the root of the plant must extend to reach the reinforcing filler hole 30 through the space between the lower part of the coupling protrusion 41 and the lower half-finished work 11b.

Although it is not shown in the drawing, waterproof coating is applied to the front surface or the inner surface of the planting portion 10 to prevent evaporation of water through the entire surface of the planting portion 10, Effect.

The drainage hole 21 formed in the drainage part 20 is positioned on the same longitudinal extension line as the upper half-mold cavity 11a or the lower half-mold cavity 11b, And is configured to communicate with the drain hole 21 of another block adjacent to the upper or lower block when the block is coupled at the correct position. (21) is preferably formed in the shape of a long hole having a width larger than a longitudinal width in a plan view.

In addition, a support block 50 made of porous concrete is further provided so that water that has passed through the drainage unit 20 can be discharged to the front of the installation site, so that the support block 50 is applied to the base end of the installation site.

The construction block according to the present invention constructed as above has a structure in which a support block 50 made of porous concrete is laid at the base end and a civil engineering block is stacked in a zigzag shape with the joints shifted above the support block 50, The process is repeated to construct the retaining wall.

The support block 50 applied to the base end is entirely made of porous concrete so that the water drained through the drainage portion 20 can be discharged to the outside of the retaining wall.

An engaging projection 41 is formed under the planting section 10 of the civil engineering block and an arched engaging groove 42 corresponding to the engaging projection 41 is formed on the planting section 10 of the civil engineering block The coupling projections 41 are naturally fitted into the coupling grooves 42 when the civil engineering blocks are stacked in the up and down staggered manner so that the civil engineering blocks stacked vertically can be firmly engaged with each other. 41 or the coupling grooves 42 so that when the civil engineering blocks are stacked in the upper and lower zigzags, they can coincide with the positions of the drain holes 21 of the other blocks adjacent to each other in the vertical direction.

When the civil engineering blocks adjacent to each other are slightly twisted to form a curved surface, the coupling grooves 42 are formed in an arcuate shape so that the engaging projections 41 of the civil engineering blocks are engaged with the arc- Since the drain hole 21 is formed in the shape of a slit having a width larger than the vertical width in a plan view, it is possible to smoothly connect the block for civil engineering with the curved surface of the block for civil engineering, Even if the distance between the drain holes 21 of adjacent blocks is slightly changed, the drain hole 21 can communicate with the drain hole 21 of another block adjacent to the other block in a certain area so that drainage can be smoothly performed.

In the civil engineering block according to the present invention, since the drainage part 20 made of porous concrete is integrally formed in the rear, it is possible to smoothly drain the building without laying gravel on the backside in the state of stacking the civil engineering blocks. So that it is possible to simplify the construction. Also, the moisture contained in the soil placed behind the reinforcing soil or the block of the civil engineering block filled in the reinforcing soil filling hole 30 can be easily removed, It is possible to escape to the drainage part 20 made of porous concrete and to drain down smoothly, thereby reducing the water pressure of the soil as a whole, so that the stability of the structure such as the retaining wall can be achieved.

Actually, the structural stability of the retaining wall constructed using the civil engineering block manufactured according to the present invention was tested as follows.

[Table 1]

[Table 2]

As shown in Table 2, when the civil engineering block manufactured according to the present invention was applied to a retaining wall, it was found that the total displacement including the hydraulic pressure significantly decreased due to the lateral displacement and the total displacement being significantly below the reference value of 25 mm. 20). This is because the water pressure including the water pressure is lowered through the water discharge.

When the retaining wall is completed, the plant grafts are planted in the respective planting holes 11. The planted plants naturally roots over time and grows by extending the roots in the direction of the reinforcing soil filled in the reinforcing soil filling hole 30 .

At this time, since the planting hole 11 is formed to be inclined downward, the plant planted through the planting hole 11 can naturally move to the reinforcing soil filled in the reinforcing soil filling hole 30, 30) is open in the vertical direction, the roots of the plant are continuously extended in the reinforcing soil, and the roots extend in the direction of the soil passing through the drainage portion (30) made of the porous concrete as well as continuous roots. And the planting hole 11 is formed in the entire planting area 10, the entire planting area 10 can be covered while the plant grows, so that the delicate environment can be changed into a natural environment.

In addition, since the planting holes 11 are inclined downward, planting of the plants is facilitated, and the reinforcing soil charged in the reinforcing soil filling holes 30 in the blocks for civil engineering works is supplied to the outside through the planting holes 11 The vegetation environment of the plant can be maintained smoothly without leakage, and the outer surface of the plant material 10 can be formed in a flat shape without protrusions, thereby improving the appearance of the plant itself. In addition, There is no protruded portion to the front wall portion of the retaining wall, so that the possibility of breakage of the retaining wall can be minimized.

In the lower portion of the planting portion 10, an upper half-working hole 11a corresponding to the upper half of the planting hole 11 is formed in a downward slope at a quarter of the entire width of the planting portion 10, A coupling protrusion 41 protrudes downward at the rear end of the planting compartment 11a and a lower half protrusion 11b corresponding to the lower half of the planting compartment 11 is formed at a position corresponding to the upper coupling protrusion of the planting compartment 10 Shaped engaging groove 42 is formed at the rear end portion of the lower half-working recess 11b while the lower half-working recess 11b is formed in a downward sloping manner. Therefore, when stacking the civil engineering blocks in the up and down staggered manner, The coupling projections 41 and the coupling grooves 42 of the adjacent civil engineering blocks adjacent to each other are coupled to each other and the upper and the lower semi-circular holes 11a and 11b are combined to form a complete planting hole 11, Plants can be planted at the boundary of the blocks, thus Given that the number of lines as well as plants that are planted here to go to the boundaries of blocks Civil becomes effective for improving the appearance beauty.

In the above description, the drainage unit 20 is made of porous concrete. However, various structures that constitute the drainage unit may exist.

For example, the drainage unit 20 includes a first partition 23 formed at a portion contacting a rear end of the reinforcing filler ball 30 in a state in which a plurality of through holes 23a are formed, and a plurality of through holes 24a A second partition wall 24 formed at a rear end of the second partition wall 24 spaced apart from the first partition wall and having a plurality of drain holes 25 formed therein and having a bottom surface between the first partition wall 23 and the second partition wall 24, The gravel 27 may be filled in the space defined by the first partition wall 23 and the second partition wall 24, the side walls of the civil engineering block and the closing surface 25, The water contained in the soil behind the civil engineering block enters the space 26 inside the first partition 23 and the second partition 24 through the through holes 23a and 24a and the gap between the gravel 27 And the drainage hole 25a. Since the space formed through the first partition 23, the second partition 24, the side walls of the civil engineering block, and the closing surface 25 is closed, the space may be filled at the time of installation in the field, It is obvious that you can fill it.

As another example, the drainage section 20 may be formed by filling a plurality of gravel bins 28 in the upper and lower open spaces between the first bank 23 and the second bank 24, The water contained in the soil behind the use block enters the space inside the first partition 23 and the second partition 24 through the through holes 23a and 24a and the gap between the gravel pockets 28 and the gap between the gravel pouch 28 So that it can be smoothly drained downward through a gap between the gravels filled in the gravel. The gravel bag 28 can be easily constructed by binding the upper part or lower part of the gravel bag 28 in a state where the gravel is filled in the netting.

In addition, it is apparent that there are various examples in which the drainage function can be performed while being integrally formed with the planting portion.

The through holes 23a and 24a formed in the first partition wall 23 and the second partition wall 24 may be inclined upward or downward or may be formed in the horizontal direction. The through holes 23a and 24a can move simultaneously with the soil and the water through the through holes 23a and 24a while the through holes 23a and 24a are formed in the first partition 23 or the second partition 24, The water flow is smooth and the movement of the soil to the space between the first partition 23 and the second partition 24 is prevented to reduce the pressure of the soil including the water pressure smoothly And when the through holes 23a and 24a are inclined downwardly, the soil moves through the through holes 23a and 24a to the space between the first partition 23 and the second partition 24 While the moisture flows through the first partition 23 beyond the inlet of the through holes 23a and 24a, The movable in the space between the second partition wall 24, it is possible to reduce the water pressure of the soil.

Therefore, the through holes 23a and 24a formed in the first partition 23 and the second partition 24 can be formed in different directions depending on the application of the civil building block according to the present invention. The through holes 23a and 24a may be inclined downward so that the water can be moved while preventing the inflow of the soil. When the soil is applied to a soil having low water content, the soil does not move actively, The through holes 23a and 24a may be configured in a horizontal direction or inclined upward.

10: Plants 11: Plants
11a: Upper half type work 11b: Lower half type work
20: drainage part 21, 26a: drainage part
23: first partition 23a, 24a, 25a: through hole
24: second partition 25: closed face
26: space 27: gravel
28: Gravel bag 30: Reinforced earth filling ball
31: side wall 41: engaging projection
42: coupling groove 50: base block

Claims (10)

A planting portion formed at a dislocation and formed with a plurality of planting holes penetrating downwardly in an anteroposterior direction so that plants are planted therein;
A reinforcing soil filling ball which is formed in succession to the planting portion and is filled with reinforcing soil to reinforce the supporting force of the structure and form the vegetation foundation of plants planted in the planting hole;
The reinforcing soil filling hole has a structure formed in succession to the reinforcing soil filling hole and having a strength capable of maintaining its shape and allowing water to pass therethrough. Thus, the water in the reinforcing soil filled in the reinforcing- Wherein the drainage unit is formed integrally so as to be sequentially positioned from the potential;
The drainage portion includes a first partition formed in a portion contacting the end portion of the reinforcing filler with a plurality of through holes formed therein and a second partition formed in a rear end spaced apart from the first partition in a state in which a plurality of through holes are formed, ;
Wherein a coupling protrusion is formed at a lower portion of the planting portion and an arc-shaped coupling groove for fitting the coupling protrusion is formed at an upper portion of the planting portion,
The bottom part between the first and second partitions is provided with a closed surface having a plurality of drainage holes. The space defined by the first partition, the second partition, the side walls of the civil block, The gravel being configured to be filled;
Wherein the coupling protrusion is formed at a position where the coupling protrusion is formed in the upper part of the planting hole and the coupling protrusion is protruded downward at the rear end of the upper half-coupling part;
Wherein a bottom half type recess corresponding to a lower half of the planting hole is formed in a downwardly inclined manner at a joint groove forming position of the planting part, the arched groove is formed at a rear end of the bottom half type work, Wherein the upper half-working and the lower half-working are combined to form a complete planting hole.
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