KR100451127B1 - Combined strengthening method of cement mortar for apartment housing floor - Google Patents

Abstract

Composite reinforcement of cement mortar for flooring of apartment houses that suppresses the occurrence of cracking of cement mortar and greatly increases thermal conductivity by forming a crack prevention layer using a small diameter copper fiber layer and a certain thickness of copper metallase on the surface of cement mortar. The method is disclosed. According to the present invention, the surface is sprayed with a small diameter of copper fiber cut to a certain length or a layer of copper metal with a rhombus mesh is laid down to produce a cement mortar for floor finishing with less cracking and greater thermal conductivity. Cement mortar for apartment floor finishing prepared according to the present invention can solve the discomfort caused by non-uniform temperature distribution as well as reducing the heating cost due to the reduction of cracks, high thermal efficiency during the initial heating.

Description

Combined strengthening method of cement mortar for apartment housing floor}

The present invention relates to a composite reinforcement method for cement mortar for floor finishing of apartments, and particularly, to form a crack preventing layer using a small diameter copper fiber layer cut to a certain length on the surface of the cement mortar and a copper metal of a certain thickness. The present invention relates to a composite reinforcement method of cement mortar for floor finishing of apartment houses that suppresses the occurrence of cracks and significantly increases thermal conductivity.

Currently, the heating method of apartment houses, such as apartments constructed in Korea, is a radiant heating method in which hot pipes are mounted on the bottom of the floor.

This heating method has many advantages such as high thermal efficiency and healthy and comfortable life, whereas cement mortar used as floor finishing material has settled cracks, plastic shrinkage and dry shrinkage cracking due to material selection defects and poor construction. There are some problems that need to be solved, such as a constant problem, such as uncomfortable due to uneven temperature distribution as the heat conduction is not fast with the crack caused by the thermal stress during the initial heating.

In order to prevent cracking, conventional cement mortar for apartment floor finishing is usually made to compensate for shrinkage cracks by adding an expansion material. Recently, a method of reinforcing with aluminum punching metal has been proposed, but this is due to the strong alkalinity of cement. There was a problem of corrosion.

The present invention has been invented to solve the above problems, the construction of the floor mortar reinforcement of the copper fiber and copper metal with a small diameter at the time of construction of the mortar cement floor mortar to increase the cracking and heat conductivity of the cement mortar The purpose is to provide a composite reinforcement method for cement mortar.

1 is a cross-sectional view showing a composite reinforcement method of the floor mortar cement mortar according to the present invention.

Figure 2 is a partially enlarged view for showing the copper metal used in the composite strengthening method of the floor mortar cement mortar according to the present invention.

Figure 3 is a graph showing the compressive and tensile strength of the floor mortar cement mortar according to the copper fiber and the expansion material mixing rate change.

Figure 4 is a graph showing the thermal conductivity of the cement mortar floor finishing according to the copper fiber and the expansion material mixing rate change.

5 is a graph showing the length change rate of the cement floor mortar mortar according to the copper fiber and the expansion material mixing rate change.

6 is a graph showing the time for each position to reach a temperature of 30 ℃ in each model test body described in Table 1.

7 is a graph showing the temperature difference according to the type change of each model test specimen described in Table 1 at the thermocouple embedding position.

Explanation of symbols on the main parts of the drawing

110: building slab 120: insulation layer

122: vinyl layer 130: foam concrete

140: heating pipe 150: cement mortar for floor finishing

160: crack prevention layer P: mesh eye

In order to achieve the above object, the present invention,

Installing a heat insulating material having a predetermined thickness on top of the slab, and laying a vinyl layer on top of the heat insulating material;

Placing and curing the foamed concrete on top of the vinyl layer, and then installing a heating pipe on the cured foamed concrete;

Preparing a cement mortar for flooring comprising a mixing ratio of 1 to 3 of water cement 60 to 70% and an expanding material of 6 to 12%; And,

Placing the prepared cement mortar on the cured aerated concrete, and sprinkling a copper fiber of a certain diameter to a predetermined thickness or spreading copper metallase on top of the cement mortar.

According to the present invention, by reinforcing copper fiber or copper metal in the cement mortar for apartment floor finishing, and by incorporating the expansion material, it significantly increases the crack suppression and thermal conductivity.

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

1 is a cross-sectional view for showing a composite reinforcement method of the bottom mortar cement mortar according to the present invention, Figure 2 shows a copper metal used in the composite reinforcement method of the floor mortar cement mortar according to the present invention Figure 3 is a graph showing the compression and tensile strength of the bottom mortar cement mortar according to the copper fiber and expansion material mixing rate change, Figure 4 is a thermal conductivity of the floor mortar cement mortar according to the copper fiber and expansion material mixing rate change Is a graph.

In addition, Figure 5 is a graph showing the length change rate of the floor mortar cement mortar according to the copper fiber and the expansion material mixing rate change, Figure 6 shows the time each position reaches a temperature of 30 ℃ in each model test specimen described in Table 1 7 is a graph showing the temperature difference according to the type change of each model test specimen described in Table 1 at the thermocouple embedding position.

Composite reinforcement method of cement mortar for apartment floor finishing according to the present invention forms a thermal insulation layer 120, such as 20mm thick styrofoam on top of the building slab 110, as shown in Figure 1, the upper portion of the thermal insulation layer 120 A double-layered vinyl layer 122 is formed, foamed concrete 130 prepared by putting a foaming agent on top of the vinyl layer 122 is poured and cured for about one week.

The heating pipe 140 made of a synthetic resin material is installed on the cured foam concrete 130, and the cement mortar 150 for floor finishing is poured into the 40 mm height. The bottom mortar cement mortar 150 is placed on top of the heating pipe 140 is manufactured by mixing 60 to 70% of water cement in a mixing ratio of 1: 3, 6 to 12% of an inflating material, and preferably about 9%.

The surface of the cement mortar 150 for pouring floor is cut into 0.1 to 0.3 mm copper fiber with a length of 9 to 36 mm, and then sprayed on the surface so as to have a mixing ratio of 0.4 to 0.8 kg / m ² or FIG. 2. As shown in Fig. 6, the same rhombus (P) having the same rhombus shape is repeatedly formed with the thickness (T) of 0.3 to 1.2 mm in the range of 6 to 12 mm in length and 12 to 24 mm in length. A layer of metal lath is laid to form a crack preventing layer 160.

Thus prepared floor mortar cement mortar 150 is added to the cement in the appropriate ratio of expansion material is less likely to crack the cement, cement spray mortar surface by spraying copper fiber or by strengthening the copper metal mortar As heat transfer increases, thermal efficiency can be maximized at initial heating.

Looking at the various characteristics of the floor mortar cement mortar according to the present invention prepared as described above, first, as shown in Figure 3, the compression and tensile strength according to the change of the mixing rate of the copper fiber and the expansion material were all increased as the age of age, In particular, in the case of copper fiber, the strength increased as the fiber mixing rate increased, which may be due to the high toughness of the copper fiber. In addition, according to the change of the incorporation rate of the expandable material, both the tensile and compressive strengths were not significantly changed as the incorporation rate was increased up to 9%.

Therefore, the proper mixing ratio of the expandable material was found to be 9% in the range that the compressive strength did not decrease.

As shown in the thermal conductivity test results, as shown in FIG. 4, it was shown to increase greatly with the increase of copper fiber incorporation rate, which may be due to the high thermal conductivity of the copper fiber itself.

In addition, the increase in the incorporation rate of the expansion material appeared to decrease slightly, which is also the result of the increase in the amount of air due to the incorporation of the expansion material and the relaxation of the internal tissue by the expansion action.

As shown in FIG. 5, the shrinkage length change rate according to age is shown to be small as the copper fiber mixing rate increases, which is analyzed as the fiber restrains the shrinkage of the cement mortar. In addition, the length change rate according to the increase in the expansion material mixing rate was found to be greatly reduced by the effect of offsetting the dry shrinkage by the expansion material.

Symbol given to each model test object in the graph Model Specimen Type Symbol Plain Copper Fiber Expandable Material + Copper Fiber Expandable Material + Heat Sink Expandable Material + Metallass (Surface) Expander + Metallases (Pipe) Expander + Metallas (Pipe on, Surface) (A) (B) (C) (D) (E) (F) (G) (H)

In the various model test specimens described in Table 1, the effect of heat conduction through the temperature measurement at the position of the top surface of the heating pipe (b) and the center surface (c) between the heating pipes with the symbol shown in the cross-sectional view of FIG. As described above, when it was evaluated at the reaching time of 30 ° C, it was confirmed that the shorter order appeared in the order of the copper fiber structure <copper metal structure <heat sink plate <plane structure <expanded material mixing structure.

In other words, if copper fiber is sprayed on the surface of cement mortar base structure or reinforced copper metal due to the excellent thermal conductivity of copper metal, the heat transfer of floor finishing mortar increases, thus not only maximizing heat efficiency but also heating cost in the initial heating. It can be reduced to some extent.

As shown in FIG. 7, the copper fiber structure was the highest and the copper metal structure was the next highest after 60 minutes of the measurement positions (b) and (c) of FIG. 1. On the other hand, the temperature change range was the smallest with the structure reinforced with copper metal on the surface and the heat sink structure with 11 ℃ and 13 ℃, respectively. This is also due to the horizontal thermal diffusion effect on the heating pipe by copper metal and heat sink.

Therefore, the measured temperature difference on the surface shows the smallest structure of the specimen G, that is, the copper metallas on the surface of the floor finishing mortar, which is the most effective reinforcing structure to prevent uneven temperature distribution.

Summarizing these test results, first, cement mortar containing 9% of expansion material showed a similar tendency to plain without mixing of expansion material, but less than half of dry shrinkage.

Second, due to the thermal conductivity of the floor finishing mortar, the temperature of the heating pipe (a) point did not change significantly with the passage of time, and at the top of the heating pipe top (b), the copper fiber structure> plain Structure> copper metal structure> heat sink structure> inflating material structure, and at the point (c), which is the center surface between heating pipes, copper fiber structure> copper metal structure> heat sink structure> plane structure> inflating material structure.

Third, the heat distribution characteristics of the floor finishing mortar were mainly evaluated by the temperature variation range of 60 minutes heating between (b) and (c) two points on the surface of the floor finishing mortar. Appeared small.

Therefore, if the expansion material is mixed into the floor finishing mortar of the apartment house and the copper fiber with excellent thermal conductivity is sprayed on the surface of the floor finishing mortar, it is possible to reduce the heating cost by reducing the cracks and high thermal efficiency during the initial heating. Placing copper metal on the surface of cement mortar for floor finishing can reduce not only cracking and high thermal efficiency, but also discomfort due to uneven temperature distribution, and it is also possible to improve the recycling efficiency by recovering the barrel metal when dismantling the floor. .

As described above, the cement mortar for apartment floor finishing according to the present invention not only can suppress the occurrence of settlement cracking, plastic shrinkage and dry shrinkage cracking of the existing structure of cement mortar for floor finishing, but also overload load and initial As heat conduction is not fast due to cracking due to thermal stress during heating, it is possible to construct high quality cement mortar for flooring by solving various problems such as discomfort due to uneven temperature distribution.

While the above has been described with reference to the preferred embodiment of the present invention, those skilled in the art will be variously modified and modified within the scope of the present invention without departing from the spirit and scope of the present invention described in the claims below. It will be appreciated that it can be changed.

Claims (3)

Iii) forming a heat insulation layer (120) having a predetermined thickness on top of the building slab (110), and forming a vinyl layer (122) on the heat insulation layer (120); Ii) The foamed concrete 130 prepared by adding the foaming agent to the upper portion of the vinyl layer 122 is poured to a predetermined thickness and cured, and then the heating pipe 140 is installed on the cured foamed concrete 130. Doing; Iii) manufacturing the floor mortar cement mortar 150 incorporating 6 to 12% of the expansion material in a water cement of 60 to 70% of the mixing ratio 1: 3; And, Ⅳ) finely cut copper fiber having a predetermined diameter on the surface of the cement mortar 150 prepared in the above step and then sprinkled with a predetermined thickness or the same material of the same thickness rhombus formed repeatedly a plurality of mesh Composite reinforcement method of cement mortar for apartment floor finishing comprising the step of spreading the metal lath to form a crack prevention layer (160). The method of claim 1, wherein the crack prevention layer 160 is cut to a copper fiber having a diameter of 0.1 to 0.3mm to a length of 9 to 36mm, and then to the surface of the cut copper fiber at a mixing ratio of 0.4 to 0.8kg / m ² Composite reinforcement method of cement mortar for floor finishing of apartment houses, characterized in that formed by spraying. The method of claim 1, wherein the crack prevention layer 160 is the same rhombus (T) of 0.3 to 1.2 mm in the thickness (T) of the line within the range of 6 to 12 mm in length (SW) and 12 to 24 mm in width (LW). P) is a composite reinforcement method of cement mortar for floor finishing of the apartment house, characterized in that formed by laminating a plurality of metal lath of copper material repeatedly formed.