KR102187882B1 - Remodeling construction method of Masato Stadium - Google Patents

Abstract

The present invention relates to a method for remodeling the Masato Stadium, the construction of which is to recover the Masato of the Masato layer in the Masato Stadium including the auxiliary base layer made of aggregate and the Masato layer made of Masato stacked on the auxiliary base layer. Step (S10); And, a screening step (S20) of sifting the recovered Masato to select only Masato of 8 to 10 mm or less; And, based on 100 parts by weight of the selected Masato, 10 to 40 parts by weight of porous balls and liquid Mixing step (S30) of mixing 10 to 30 parts by weight of a natural solidifying agent to form a functional Masato; And, a first flattening step of flattening the upper portion of the auxiliary base layer exposed to the outside by recovering the Masato of the Masato layer ( S40); And, a laying step (S50) of forming a functional Masato layer by laying a functional Masato layer on the top of the auxiliary base layer; And, a second flattening step of flattening the upper portion of the functional Masato layer laid as the auxiliary base layer (S60); As characterized in that consisting of,
A natural solidifying agent that collects and recycles Masato that constitutes the existing Masato layer, and aggregates Masato and porous balls into a number of fine lumps together with porous balls that induce smooth drainage of the selected Masato. The existing Masato Stadium is remodeled by adding and re-installing the functional Masato, thus maintaining the advantages of the Masato Stadium very simply and economically, but the occurrence of scattering dust generated in the conventional Masato Stadium In addition to preventing chiseling and soiling, there is an effect of preventing loss of Masato or damage to surroundings due to the loss of Masato through smooth permeation and drainage.
In addition, since it is a method of recycling and remodeling Masato in the existing Masato Stadium, it is not only very economical, but also because the remodeling process is simple, the cost and time required are low, so that the application of construction can be secured.

Description

Remodeling construction method of Masato Stadium

The present invention relates to a remodeling construction method of Masato Stadium, and more particularly, to select Masato that can be recycled by recovering Masato constituting the existing Masato layer, and a porous ball that induces smooth drainage to the selected Masato The Masato Stadium is very simple and economical by remodeling the existing Masato Stadium by adding a natural solidifying agent that aggregates Masato and Porous Balls into a number of fine lumps to form a functional Masato, and re-installing the functional Masato. While maintaining the merits of Masato, it not only prevents the occurrence of scattering dust, chives, and dirt that occur in the conventional Masato Stadium, but also damages the surroundings due to the loss of Masato or the loss of Masato through smooth pitching and drainage. It relates to the remodeling construction method of Masato Stadium that can prevent the problem.

In recent years, various harmful substances (materials that cause cancer or skin diseases), such as lead (Pb) and zinc (Zn), have been detected in artificial turf. In hot summer, the surface of artificial turf is formed at high temperature, so children with weak skin As safety accidents such as easy burns occur, there is a trend of increasing numbers of stadiums that replace stadiums using artificial turf and return to the past, eco-friendly and semi-permanent Masato (soil) stadiums.

However, in the Masato Stadium as described above, due to the nature of the soil, scattering dust is easily generated by the wind, and when it rains, the surface is frequently cracked, causing a safety accident due to the user's fall, and the soil is easily pulled in the process of using the stadium. There was a problem that the management of the stadium was somewhat inconvenient due to the occurrence of the phenomenon.

In addition, the existing Masato Stadium has a problem that the pitching and drainage through Masato is somewhat not smooth, so when rainwater flows through the surface of the stadium, Masato (soil) is transported and lost or damages the area around the stadium.

Therefore, there is a need for an economical remodeling method of Masato Stadium that can solve the problems of Masato Stadium as described above, but can recycle the existing Masato Stadium.

The present invention has been proposed in order to solve the problems as described above, the object of which is to recover the Masato constituting the existing Masato layer and select the Masato that can be recycled, and to induce smooth drainage to the selected Masato. It is very simple and economical by remodeling the existing Masato Stadium by adding a natural solidifying agent that aggregates Masato and porous balls into a number of fine lumps together with porous balls to form functional Masato, and re-installing the functional Masato. It maintains the advantages of Masato Stadium, but prevents the occurrence of scattering dust, chives, and dirt that occur in the conventional Masato Stadium, and also prevents the loss of Masato or the loss of Masato through smooth throwing and draining. It is to provide a remodeling construction method of Masato Stadium that can prevent damage.

In addition, since it is a method of recycling and remodeling Masato of the existing Masato Stadium, it is not only very economical, but also because the remodeling process is simple, the cost and time required are low, providing a method of remodeling the Masato Stadium that can secure the versatility of construction. have.

The remodeling construction method of the Masato Stadium according to the present invention for achieving the above object is a Masato of the Masato layer in the Masato Stadium, which includes an auxiliary base layer made of aggregate and a Masato layer composed of Masato stacked on top of the auxiliary base layer. Recovery step of recovering (S10); And, a screening step (S20) of selecting only Masato of 8 to 10 mm or less by sieving the recovered Masato; And, based on 100 parts by weight of the selected Masato, 10 to 40 weight of porous balls Mixing step (S30) of mixing parts and 10 to 30 parts by weight of a liquid natural solidifying agent to form a functional Masato; And, a first for flattening the upper portion of the sub-base layer exposed to the outside by recovering the Masato of the Masato layer Flattening step (S40); And, laying step (S50) of forming a functional Masato layer by placing a functional Masato on the top of the auxiliary base layer; And, an agent for flattening the upper portion of the functional Masato layer laid as the auxiliary base layer. 2 flattening step (S60); is made including,
The thickness of the functional Masato layer laid in the laying step (S50) is constructed to be 8 to 15 cm,
If the thickness of the functional Masato layer is smaller than the thickness of the existing Masato layer, an aggregate replenishment step (S70) of filling and replenishing the aggregate to the upper portion of the sub-base layer by the difference thickness (S70); further comprising, the aggregate replenishment step (S70) is performed before the first flattening step (S40),
In the second flattening step (S60), a flattening process (S61) of scraping the uneven upper surface of the functional Masato layer on which the functional Masato is laid using a grader to planarize the surface of the functional Masato layer, It is characterized in that it comprises a hydrolysis step (S62) of spraying the agent, and a compaction step (S63) of flattening the surface by pressing the upper layer of the functional Masato layer with a combi roller.

delete

delete

delete

As described above, according to the remodeling construction method of the Masato Stadium according to the present invention, a porous ball that collects Masato constituting the existing Masato layer and selects Masato that can be recycled, and induces smooth drainage to the selected Masato The Masato Stadium is very simple and economical by remodeling the existing Masato Stadium by adding a natural solidifying agent that aggregates Masato and Porous Balls into a number of fine lumps to form a functional Masato, and re-installing the functional Masato. While maintaining the merits of Masato, it not only prevents the occurrence of scattering dust, chives, and dirt that occur in the conventional Masato Stadium, but also damages the surroundings due to the loss of Masato or the loss of Masato through smooth pitching and drainage. There is an effect that can prevent.

In addition, since it is a method of recycling and remodeling Masato in the existing Masato Stadium, it is not only very economical, but also because the remodeling process is simple, the cost and time required are low, so that the application of construction can be secured.

1 is a block diagram of a remodeling construction method of Masato Stadium according to an embodiment of the present invention
2 is a view for explaining the remodeling construction method of the Masato Stadium shown in FIG. 1

A method for remodeling Masato Stadium according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Detailed descriptions of known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention will be omitted.

1 and 2 are diagrams illustrating a method for remodeling Masato Stadium according to an embodiment of the present invention, and FIG. 1 is a block diagram of a method for remodeling Masato Stadium according to an embodiment of the present invention, and FIG. Each of the drawings for explaining the remodeling construction method of the Masato Stadium shown in is shown.

As shown in the drawing, the remodeling construction method 100 of the Masato Stadium according to an embodiment of the present invention includes a recovery step (S10), a sorting step (S20), a mixing step (S30), and a first flattening step. It includes (S40), a laying step (S50), and a second flattening step (S60).

1 and 2A, the recovery step (S10) includes an auxiliary base layer 1 made of aggregate and a Masato layer 2 made of Masato stacked on top of the auxiliary base layer 1 This is the process of recovering Masato from Masato layer (2) at Masato Stadium.

For the remodeling of the existing Masato Stadium, this is a process of removing and recovering the existing Masato layer (2) where phenomena such as scattering dust, chives, and dirt are generated, and the reason for such recovery is the selection step (S20) to be described later. This is to induce economical remodeling by minimizing the cost of remodeling the stadium by selecting and reusing only Masato that can be used in the park.

As shown in Figs. 1 and 2A, the sorting step (S20) is a process of sifting the recovered Masato and selecting only Masato of 8 to 10 mm or less.

That is, in the sorting step (S20), the aggregate of the sub-base layer (1) partially recovered in the process of recovering Masato in the collection step (S10) and the relatively large or lumped Masato are filtered through a sieve to facilitate use. This is the process of selecting only Masato.

As shown in Figure 1, the mixing step (S30) is a process of forming a functional Masato by mixing 10 to 40 parts by weight of a porous ball and 10 to 30 parts by weight of a liquid natural solidifying agent with respect to 100 parts by weight of the selected Masato to be.

Here, the porous ball secures excellent water permeability and drainage of the functional Masato layer 10, while minimizing the transport (loss) of Masato due to external environments (wind, rain, etc.) to stabilize the surface of the functional Masato layer. If the porous ball is added in an amount of less than 10 parts by weight based on 100 parts by weight of Masato, the water permeability and stabilization of the surface of the functional Masato layer is somewhat low, and if it exceeds 40 parts by weight, the characteristic characteristics of Masato may be lost. Therefore, it is preferable to add and mix 10 to 40 parts by weight of the porous ball based on 100 parts by weight of Masato.

Such a porous ball can be formed into a spherical shape by adding and mixing wood powder and an adhesive to a ceramic material, and then plasticizing at a high temperature to form a ball having a predetermined hardness.At this time, the wood powder is burnt and lost to the ball surface. It is manufactured so that pores are naturally formed in the.

Therefore, the porous ball can be expected to sterilize harmful bacteria remaining in the stadium and beneficial effects on the human body due to the emission of far-infrared rays and negative ions, which are characteristic of ceramics, as well as the process of manufacturing the porous ball to further increase these effects. In addition to ceramic materials, it can be produced including ocher, white clay, kaolin, cloisonne, sericite, and pyrophyllite.

Here, the porous ball is not limited to a method of plastic processing, and of course, a mineral having a porosity itself, for example, zeolite, can be processed and used in a predetermined shape.

In addition, the liquid natural solidifying agent is a composition that aggregates Masato and porous balls to form fine small lumps in a stiff form to prevent scattering dust, bone digs, and soil pulling phenomena occurring in the conventional Masato Stadium. If the natural supernatant is added in an amount of less than 10 parts by weight per 100 parts by weight of Masato, it cannot effectively coagulate the Masato and the porous balls to effectively prevent scattering dust, dents, and dirt. If it is added in excess of 30 parts by weight, the functional Masato layer It is preferable to add 10 to 30 parts by weight of the liquid natural solidifying agent with respect to 100 parts by weight of Masato, since the inside is sealed and prevents water permeation and drainage.

Here, the liquid natural solidifying agent is produced including seaweed alginic acid powder that increases viscosity and soda silicate that stabilizes the land in an eco-friendly natural latex, but is not limited to such a composition.

1 and 2B, the first flattening step (S40) is a process of flattening the upper portion of the auxiliary base layer 1 exposed to the outside after the Masato of the Masato layer 2 is recovered.

That is, in the process of recovering the Masato layer in the recovery step (S10), since the upper portion of the auxiliary base layer 1 is somewhat damaged, the upper portion of the auxiliary base layer 1 is flattened to be installed later in the laying step (S50). Induces the functional Masato to be stably installed.

Here, the process of the first flattening step (S40) and the process of the sorting and mixing steps (S20, S30) may be performed simultaneously.

As shown in FIGS. 1 and 2C, the laying step (S50) is a process of forming a functional massato layer 10 by laying a functional massato on the top of the auxiliary base layer 1.

Functional Masato that is laid in this way maintains Masato's unique strengths, but prevents the occurrence of scattering dust, chiseling, and soil pulling that occur in the conventional Masato Stadium, and a functional Masato layer (10) that can secure excellent water permeability and drainage. Is formed by

On the other hand, the thickness (t) of the functional Masato layer 10 to be laid in the laying step (S50) is constructed to be 8 to 15 cm,

At this time, as shown in FIGS. 1 and 2B, if the thickness t of the functional Masato layer 10 is smaller than the thickness of the existing Masato layer, the difference is as much as the upper portion of the auxiliary base layer 1 To further include an aggregate replenishment step (S70) of filling and replenishing the aggregate.

That is, the functional Masato layer 10 formed in the remodeling construction method 100 of the Masato Stadium of the present invention has a stabilized surface to prevent loss of Masato due to the external environment, and thus the Masato layer (2) of the existing Masato Stadium In contrast, even if the thickness is slightly smaller, it can lead to stable use and management of the stadium.

Therefore, in the existing Masato Stadium, the Masato layer 2 is formed to a thickness of 15 to 25 cm, whereas the functional Masato layer 10 is formed to a thickness t of 8 to 15 cm. The overall height of the stadium built by the remodeling construction method 100 may be lowered, and in this case, the use of the stadium may be somewhat inconvenient because the height of the stadium is not balanced with the surrounding facilities installed in accordance with the height of the existing Masato stadium. By compensating the height of the lowered level through S70), it is formed equal to the height of the existing Masato Stadium.

Here, the aggregate replenishment step (S70) is performed before the first flattening step (S40) so that the sub-base layer (1) supplemented with the aggregate is planarized through the first flattening step (S40).

Typically, a drainage pipe is installed below the subbase layer 1 to ensure drainage, and such a drainage pipe may become deteriorated or lost in function due to deterioration in the process of using the stadium for a long period of time. After removal, replacement of the old drainage pipe may be required, and the remodeling construction method 100 of the Masato Stadium of the present invention can reinforce the drainage property through the auxiliary base layer 1 by supplementing aggregates on the upper part of the auxiliary base layer 1. Since there is no need to perform the process of replacing the old drain pipe, the budget and time required to replace the drain pipe can be significantly reduced, thereby securing the construction versatility of the remodeling construction method of the stadium.

As shown in FIGS. 1 and 2D, the second flattening step (S60) is a process of flattening the upper portion of the functional Masato layer 10 laid as the sub-base layer 1, and a flattening process (S61). And, it consists of an add process (S62), and a compaction process (S63).

The flattening step (S61) is a process of firstly flattening the uneven upper surface of the functional Masato layer 10 on which the functional Masato is laid by using a grader.

The hydrolysis step (S62) is a process of spraying a liquid natural solidifying agent onto the surface of the upper layer of the functional Masato layer 10.

Here, the reason for spraying the liquid natural solidifying agent into the upper layer of the functional Masato layer 10 is to induce the surface of the functional Masato layer 10 to be further stabilized by strengthening the cohesive force of the upper layer of the functional Masato layer 10 to be.

At this time, the functional Masato layer 10 is in a state that is stably agglomerated by a liquid natural solidifying agent that is basically included, so the liquid natural solidifying agent sprayed to the upper layer of the functional Masato layer 10 is diluted with water. You can also spray.

In the compaction step (S63), the upper layer of the functional Masato layer 10 is pressed with a combi roller to secondarily flatten the surface.

A liquid natural solidifying agent sprayed onto the upper layer surface during the process of flattening the upper layer surface of the functional Masato layer 10 very evenly through the compaction process (S63) and pressing the upper layer portion of the functional Masato layer 10 In this way, the Masato of the upper layer is more effectively agglomerated to induce more excellent stabilization of the surface of the functional Masato layer 10.

In the remodeling construction method 100 of the Masato Stadium of the present invention, which consists of the above process, the Masato that constitutes the existing Masato layer 2 is recovered, selects Masato that can be recycled, and smoothly drains the selected Masato. It is very simple by remodeling the existing Masato Stadium by adding a natural solidifying agent that aggregates Masato and porous balls into a number of fine lumps together with the inducing porous ball to form a functional Masato and re-install the functional Masato. And while maintaining the economical advantages of Masato Stadium, it not only prevents the occurrence of scattering dust, chiseling, and dirt that occur in the conventional Masato Stadium, but also prevents the loss of Masato or the loss of Masato through smooth throwing and draining. There is an effect that can prevent damage to the surroundings.

In addition, since it is a method of recycling and remodeling Masato in the existing Masato Stadium, it is not only very economical, but also because the remodeling process is simple, the cost and time required are low, so that the application of construction can be secured.

Masato Stadium is remodeled by the remodeling construction method 100 of the Masato Stadium according to the embodiment of the present invention having the above configuration, but the thickness of the Masato layer 2 of the existing Masato Stadium is 15 cm, and is newly constructed. It is assumed that the thickness t of the functional Masato layer 10 is formed to be 10 cm.

First, as shown in Fig. 2A, the Masato layer 2 is recovered from the existing Masato Stadium, and the recovered Masato is sieved to select only Masato of 8 to 10 mm or less. (S10),(S20)

Then, a porous ball and a liquid natural solidifying agent are added and mixed to the selected Masato to form a functional Masato, but 10 to 40 parts by weight of a porous ball and 10 to 30 parts by weight of a liquid natural solidifying agent are mixed with respect to 100 parts by weight of Masato. Make it possible. (S30)

Then, as shown in Fig. 2b, the thickness of the Masato layer 2 of the existing stadium is 15 cm, and the thickness t of the functional Masato layer 10 to be newly constructed is 10 cm, resulting in a thickness difference of 5 cm from each other. Therefore, in order to compensate for this difference in thickness, aggregate is added to the upper portion of the sub-base layer 1 to increase the thickness of the sub-base layer 1 by 5 cm, and then the upper part of the sub-base layer 1 is flattened. (S40),(S70)

Then, a functional Masato is laid on the top of the sub-base layer 1 to form a functional Masato layer 10, but the thickness of the functional Masato layer 10 is 10 cm. (S50)

Then, as shown in FIG. 2D, after first flattening the uneven upper surface of the functional Masato layer 10 with a grader, in a state in which a liquid natural solidifying agent is sprayed onto the upper surface of the functional Masato layer 10 The upper layer of the functional Masato layer 10 is pressed with a combi roller to make the surface evenly and secondarily planar to complete the remodeling of the Masato Stadium. (S60)

Although the remodeling construction method 100 of the Masato Stadium of the present invention was described in an example using the existing Masato Stadium, the remodeling construction method of the Masato Stadium of the present invention (100) after removing the artificial turf in the upper layer from the existing artificial turf stadium. Of course, it can be applied in a way to form a functional Masato layer in place of artificial turf by applying the process of.

The present invention has been described with reference to the embodiments shown in the accompanying drawings, but these are illustrative and are not limited to the above-described embodiments, and various modifications and equivalent embodiments are possible from those of ordinary skill in the art. You can understand the point. In addition, it goes without saying that modifications can be made by those skilled in the art within a range that does not impair the spirit of the present invention. Therefore, the scope of claiming the rights in the present invention is not defined within the scope of the detailed description, but will be limited by the claims and the technical spirit thereof to be described later.

1. Subbase layer 2. Masato layer
10. Functional Masato layer t. thickness
S10. Recovery step S20. Screening step
S30. Mixing step S40. First leveling step
S50. Installation step S60. 2nd leveling step
S61. Flattening process S62. Watering process
S63. Compaction process S70. Aggregate replenishment step
100. Masato Stadium remodeling construction method

Claims (3)

A recovery step (S10) of recovering the Masato of the Masato layer 2 at the Masato Stadium including the sub-base layer 1 made of aggregate and the Masato layer 2 made of Masato stacked on top of the sub-base layer 1 ;
A screening step (S20) of sifting the recovered Masato and selecting only Masato of 8 to 10 mm or less;
Mixing step (S30) of mixing 10 to 40 parts by weight of a porous ball and 10 to 30 parts by weight of a liquid natural solidifying agent to form a functional Masato based on 100 parts by weight of the selected Masato;
A first flattening step (S40) of flattening the upper portion of the auxiliary base layer 1 exposed to the outside by recovering the Masato of the Masato layer 2;
Laying step (S50) of forming a functional Masato layer 10 by placing a functional Masato on the top of the auxiliary base layer (1); And
Containing a second flattening step (S60) of flattening the upper portion of the functional Masato layer 10 laid as the sub-base layer (1),
The thickness (t) of the functional Masato layer 10 to be laid in the laying step (S50) is constructed to be 8 to 15 cm,
If the thickness (t) of the functional Masato layer 10 is less than the thickness of the existing Masato layer, the aggregate replenishment step (S70) of filling and replenishing the aggregate to the upper portion of the auxiliary base layer 1 by the difference thickness; Further comprising, the aggregate replenishment step (S70) is performed before the first flattening step (S40),
The second flattening step (S60) includes a flattening step (S61) of scraping and flattening the uneven upper surface of the functional massato layer 10 on which the functional massato is installed using a grader (S61), and the functional massato layer (10). Masato Stadium, characterized in that it comprises a hydrolysis step (S62) of spraying a liquid natural solidifying agent onto the upper layer surface, and a compaction step (S63) of evenly flattening the surface by pressing the upper layer of the functional Masato layer 10 with a combi roller. Remodeling construction method. delete delete

Images