KR20230064567A - Filling layer drainage method for sidewalk block - Google Patents

Abstract

In the present invention, after stirring cement and aggregate in a dry method, vibration compaction is performed in a mold to form a drainage block having water permeability, and it is installed vertically and horizontally in the subbase layer on which the paving block is laid, so that rainwater permeating into the sand layer and the aggregate layer is removed from the subbase layer. It relates to a subbase layer drainage method for a pavement road block in which differential settlement of the pavement block is prevented and the subbase layer is not weakened by letting the roadbed escape along the permeable drainage block without stagnation.
To this end, in the present invention, a sub-base layer is formed on the sub-base layer, an aggregate layer and a sand layer are sequentially stacked on the sub-base layer, and then a pavement block is constructed, and a drainage block connecting the aggregate layer and the sub-base layer is vertically and horizontally connected to the sub-base layer. landfill; The drainage block is composed of cement and aggregate, which are mixed at a water-cement ratio of 20% by weight or less and then put into a mold to impart water permeability during vibration compaction; The drainage block is characterized in that the upper surface of the square is configured in a trapezoidal shape that is wider than the lower surface of the square so that it is buried in the subbase layer and endures without sinking.

Description

Subbase layer drainage method for sidewalk block {Filling layer drainage method for sidewalk block}

The present invention relates to a subbase layer drainage method for a paving block, and more particularly, after stirring cement and aggregate in a dry method and then vibrating compaction in a mold to form a drainage block in the shape of a top base base having water permeability, the paving block By installing it vertically and horizontally on the subbase layer to be laid, rainwater permeating into the sand layer does not stagnate in the subbase layer and flows out to the roadbed along the permeable drainage block, thereby preventing differential settlement of the pavement block and preventing the subbase layer from weakening. It is about layer drainage.

In general, since rainwater does not permeate into the pavement block and flows into the rainwater outlet of the road, groundwater inside the roadbed where the pavement block is installed is insufficient. In particular, when heavy rain falls, rainwater quickly flows into the river, resulting in natural disasters such as river flooding. there was Considering this, permeable pavement blocks were developed. Various types of pavement blocks have been developed for the purpose of preventing the depletion of groundwater by permeating rainwater into the roadbed and also preventing flooding of the road during heavy rain.

However, even if the permeability of the roadbed block is too good, there is a problem in that rainwater is stagnant in the subbase layer above the roadbed and does not permeate into the roadbed. The subbase layer is constructed by compacting a mixture of soil and gravel at a height of 100 mm to 300 mm from the road bed, and serves to support the road or sidewalk. Since these subbase layers are impermeable without securing air gaps, when rainwater quickly flows in due to heavy rain, rainwater stagnates in the subbase layers, causing differential settlement.

In view of this, Korean Patent No. 466889 forms a structure capable of draining the pavement block installed on the sidewalk of the road so that rainwater on the surface of the pavement can be treated in the pavement block during the rainy season, so that rainwater does not collect on the subbase layer. In addition, a sidewalk block for roads has been proposed to prevent the subsidence of the sidewalk blocks due to external load and deformation of the roadbed due to mutual fastening between the sidewalk blocks, so as not to cause inconvenience to pedestrians.

However, since the sides of each walkway block are coupled with a connecting member along the length direction, workability is difficult, and holes must be drilled in each walkway block, so the holes are exposed to the outside and foreign substances flow into the drain pipe. There was a problem.

The inventor of the present application has proposed a block drainage system in Publication No. 10-2016-0130596. This is so that rainwater flowing into the sand layer and aggregate layer along the permeable hole of the sidewalk block (sidewalk and driveway block) does not stay in the subbase layer and flows into the roadbed. By doing this, since rainwater does not stagnate in the subbase layer, it does not flow back to the paved road block, and lifting or sinking of the paved road block due to differential settlement does not occur.

However, the above patent has a problem in that the subbase layer is weakened due to a drain pipe embedded in the subbase layer, and also has a problem of poor workability because a cover is installed at the top of the drainpipe to prevent the drainpipe from being clogged and a core material for inducing rainwater is installed.

The present invention was developed in view of the problems of the prior art, and the object of the present invention is to stir cement and aggregate in a dry method and then vibrate compaction in a mold to form a drainage block in the shape of a top base with water permeability. By installing it vertically and horizontally on the subbase layer to be laid, rainwater permeating into the sand layer does not stagnate in the subbase layer and escapes to the roadbed along the permeable drainage block, thereby preventing differential settlement of the pavement block and also preventing the weakening of the subbase layer. It is to provide a sub-base drainage method for a sub-base layer with excellent workability because it can be made in the form of a top base foundation and easily installed on the sub-base layer.

To this end, in the present invention, a sub-base layer is formed on the sub-base layer, a sand layer and a road block are constructed on the sub-base layer, and drainage blocks in the form of a top foundation connecting the sand layer and the sub-base layer are buried vertically and horizontally; The drainage block is composed of cement and aggregate, which is mixed at a water-cement ratio of 20% by weight or less and then put into a mold to impart water permeability during vibration compaction; The drainage block is characterized in that the upper surface of the square is formed in a trapezoidal shape wider than the lower surface of the square, so that rainwater is induced to flow from the subbase to the subbase when it is embedded in the subbase.

According to the present invention, since the drainage block in the form of a top base layer embedded in the subbase layer has water permeability in order to reinforce the subbase layer, rainwater flowing into the subbase layer flows from the drainage block to the roadbed, so that rainwater does not accumulate in the subbase layer, In particular, there is an advantage in that, when the subbase layer becomes soft due to stagnation of rainwater, differential settlement occurs and the problem that the surface of the pavement block is curved is also solved.

The drainage block is manufactured in the form of a top base and also serves to reinforce the sub-base layer when embedded in the sub-base layer. In addition, since the drainage block is made in the process of vibratory compaction in the mold through the dry method in the same way as the method of forming the block, the productivity is excellent because a separate molding machine is not required, and the drainage block can be fitted to the surface of the auxiliary base layer. Through a simple method of pressing the surface of the subbase layer with a fork crane to make a mark, the drainage block is not damaged and embedded in the subbase layer, so there are advantages such as easy workability while maintaining water permeability.

1 is a conceptual diagram of a subbase layer in which a drainage block of a first embodiment of the present invention is installed
Figure 2 is a plan view of a mold for forming a drainage block of the first embodiment of the present invention
Figure 3 is a perspective view of the drainage block of the first embodiment of the present invention
4 is a conceptual diagram of a fork crane for constructing a drainage block of the first embodiment of the present invention
5 is a perspective view of a drainage block of a second embodiment of the present invention
6 is a plan view of a drainage block of a second embodiment of the present invention
7 is a perspective view of a drainage block of a third embodiment of the present invention
8 is a perspective view of a drainage block according to a fourth embodiment of the present invention

1 to 4, the permeable drainage block of the first embodiment of the present invention is a mixture of cement and aggregate through a dry method, cement: aggregate is mixed in a ratio of 2.5: 6.5, and the aggregate has a size of 5 to 15 mm , the water-cement ratio is less than 20% by weight, and the water permeability is improved. Alternatively, cement and aggregate are mixed through a dry method, and the aggregate uses a single particle size in the range of 3 to 8 mm to provide sufficient strength and voids, and 20 to 25 parts by weight of water (water/cement ratio 0.2) based on 100 parts by weight of cement ~ 0.25) agitated by a dry method.

The aggregate mixed by this dry method is put into the mold 40, which is divided into a plurality of compartments through the zigzag partition walls 41 to provide space for forming the drainage block 10 . After the aggregate is put into the mold 40 and vibration compaction is applied, the aggregate is formed into a drainage block 10 through a dry method, and it is transported to a drying field, dried with hot air for a certain period of time, and then naturally dried outdoors. The drainage block 10 of the example is completed.

The drainage block 10 is in the form of a top base with a wide top and a narrow bottom, and is composed of a quadrangular upper surface portion 11 and a rectangular lower surface portion 12 with a smaller area than the upper surface portion 11, and the front and The side surface is composed of parallel front and rear side surface parts 13, and the left and right sides are composed of left and right side surface parts 14 that form an inclined surface that becomes narrower from the upper surface part 11 to the lower surface part 12. Therefore, the drainage block 10 is composed of a triangular pyramid shape with front and rear sides parallel and lower left and right sides as a whole, so that when it is embedded in the subbase layer 3, it can remain in place without turning off.

In addition, the cover 21 in the form of a triangular pyramid surrounding the drainage block 10 may be made of water-impervious synthetic resin so that the side surface of the drainage block 10 is not exposed to the subbase layer 3. Therefore, when rainwater is guided to the drainage block 10, it flows directly to the subgrade layer 4 without permeating into the subbase layer 3, but the cover 21 is not an essential component. In addition, the subgrade 4 may further include a drain pipe 22 in contact with the bottom portion 12 of the drain block 10 . Reference numeral 5 is a nonwoven fabric laid between the sand layer 2 and the auxiliary base layer 3.

A plurality of drainage blocks 10 of the first embodiment of the present invention made in this way are embedded in the subbase layer 3 vertically and horizontally, and for convenience of construction, a block groove for embedding the drainage block 10 and the cover 21 ( 20) is required. In one embodiment of the present invention, a pressing plate 31 is provided at the end of the arm 30 of the excavator in order to form the block groove 20 on the subbase layer 3, and the pressing plate 31 has projections 32 in all directions is provided The protrusion 32 is formed in the same shape as the drainage block 10, and when each protrusion 32 is driven into the subbase layer 3 by the pressing plate 31 through the arm 30 of the excavator, the Block grooves 20 are formed in the subbase layer 3 by the protrusions 32 at once.

The drainage block construction process of the first embodiment of the present invention is as follows. Four protrusions 32 are provided on the pressing plate 31 so that four block grooves 20 are formed per square meter of the subbase layer 3. The press plate 31 having the protrusion 32 is embedded in the surface of the subbase layer 3 through the operation of the excavator, and a plurality of block grooves 20 are formed in the subbase layer 3 by the repeated operation of the excavator. Thereafter, the drainage block 10 and the cover 21 are inserted into each block groove 20 so that the upper surface portion 11 coincides with the surface of the subbase layer 3, and the lower surface portion 12 communicates with the surface of the subgrade layer 4. let it do At this time, the drain pipe 22 previously driven into the subgrade 4 communicates with the bottom part 12. In addition, after constructing the nonwoven fabric 5 and the sand layer 2 sequentially on the subbase layer 3, the road block 1 is laid vertically and horizontally on top of the sand layer 2.

In the first embodiment of the present invention constructed as described above, the drainage block 10 penetrates the subbase layer 3 and serves to connect the sand layer 2 and the subgrade layer 4, and in particular, the drainage block 10 has an upper surface. Since the part 11 is composed of a larger area than the bottom part 12, and both left and right side parts 14 are composed of downwardly reduced and inclined surfaces, even under pressure, the subbase layer 3 is not penetrated and the subbase layer 3 is not entered into the subgrade 4 don't Therefore, even if vehicles pass frequently or a strong concentrated load is applied to the sidewalk block 1, the drainage block 10 does not move, so the subbase layer 3 and the roadbed 4 are stabilized. ) and the sand layer (3), and when introduced to the surface of the subbase layer (3), it is discharged to the road bed (4) through the drainage block (10), so that the sand layer (2) above the subbase layer (3) is prevented from fluidization There is an advantage in that differential settlement of the pedestrian block 1 is prevented.

5 is a second embodiment of the present invention, which has the same configuration as the first embodiment. Only the drain block 10a is divided into two, and a plurality of drain passages 15 are provided on the divided corresponding surfaces to form one in contact with each other. The divided drainage block 10a has an upper surface portion 11a and a lower surface portion 12a with different widths, front and rear side surfaces 13a provided side by side, and the left and right side surfaces 14a narrower toward the bottom. It is composed of an oblique shape.

Therefore, when a pair of drain blocks 10a divided from each other are combined into one, since a plurality of drain passages 15 are provided vertically on the corresponding surface, rainwater can flow to the roadbed more quickly.

7 is a third embodiment of the present invention, which has the same configuration as the first embodiment. That is, the drainage block 10b has an upper surface portion 11b and a bottom portion 12b of different widths, the front and rear side surfaces 13b are provided side by side, and the left and right side surfaces 14b have a slope that becomes narrower toward the bottom. consists of a form In addition, a plurality of drainage passages 16 are formed in the front and rear side parts 13b and the left and right side parts 14b to serve as passages through which rainwater flows.

When the third embodiment of the present invention configured as described above is buried in the subbase layer 3 in the same manner as the first embodiment, it induces rainwater to flow to the roadbed while preventing differential settlement of the paved road block. Since the drainage block 10b is porous, rainwater permeates into the subgrade and flows into the subgrade. In particular, since rainwater flows quickly through the drainage passages 16 formed on the four sides, there is an advantage during heavy rain.

8 is a fourth embodiment of the present invention, the drainage block (10c) is provided with a top surface portion (11c) and a bottom surface portion (12c) of different widths as in the first embodiment, and the front and rear side surfaces (13c) are side by side It is provided, and the left and right side parts 14c are composed of an inclined shape in which the width decreases as it goes downward. And the upper part of the left and right side parts 14c has wing parts 17 that protrude horizontally in directions away from each other. When the wing part 17 is placed on the subbase layer 3, it serves to suppress sagging.

When the fourth embodiment of the present invention configured as described above is buried in the subbase layer 3 in the same manner as the first embodiment, it induces rainwater to flow to the roadbed while preventing differential settlement of the paved road block. Since the drainage block 10c is porous, rainwater permeates into the subgrade and flows into the subgrade. In addition, since the wings 17 protrude outward from the top of the left and right side surfaces 14c, the area placed on the subbase layer 3 is increased to help suppress the sagging of the drainage block 10c.

1: road block 2: sand layer
3: Subbase 4: Subgrade
10: drainage block 11: upper surface
12: bottom part 13: front and rear side parts
14: left and right side parts 15, 16: drain passage
17: wing 20: block groove
30: arm 31: press plate
32: protrusion

Claims (6)

A sub-base layer is formed on the sub-base layer, a sand layer and pavement blocks are constructed on the sub-base layer, and drainage blocks in the form of a top foundation connecting the sand layer and the sub-base layer are buried vertically and horizontally in the sub-base layer;
The drainage block is composed of cement and aggregate, and 20 to 25 parts by weight of water is mixed with respect to 100 parts by weight of cement, and injected into a mold to impart water permeability during vibration compaction;
The drainage block is composed of a trapezoidal shape in which the upper surface of the square is wider than the bottom of the square, so that when embedded in the subbase, rainwater is induced to flow from the subbase to the roadbed. According to claim 1,
The drainage block is composed of front and rear sides with parallel front and side surfaces, and the left and right sides are composed of left and right side surfaces with inclined surfaces that become narrower toward the bottom. According to claim 1,
Two of the drainage blocks form a pair, and a plurality of drainage passages are formed on the opposite surfaces corresponding to each other to allow rainwater to flow. According to claim 1,
The drainage block has a plurality of drainage passages formed on the four sides so that the rainwater flows quickly. According to claim 1,
The drainage block further includes wings protruding and extending to both sides of the top surface, and when the wings are placed on the subbase layer, the drainage block is suppressed from sagging. According to claim 1,
A pressure plate is provided at the tip of the excavator arm;
The pressing plate is provided with a plurality of projections identical in shape to the drainage block, so that a block groove into which the drainage block is inserted is made by the projections in the process of pressing the pressing plate to the auxiliary base layer, characterized in that drainage method.

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