KR101274220B1 - Heat Isolathing block or Cool Isolathing block use of the Appearance by Convection and Method OF Producing The same - Google Patents

Abstract

In the present invention, after forming a black pigment layer on the upper surface of the general aggregate layer, and then forming a heat shield aggregate layer on the upper surface, the temperature of the upper surface of the block is lower than the surrounding temperature due to the convection of hot heat radiated in summer. The invention relates to a heat shield or a cold block and a method of manufacturing the same that can significantly reduce the heat island phenomenon.
The present invention for this purpose is a coarse aggregate is mixed pigment layer for absorbing heat; And an upper layer formed on an upper surface of the pigment layer to block heat.
The heat shield or cold block of the present invention is used in the floor of the park, the floor of the apartment complex, the wall of the building, etc., while the air is circulated by the convection phenomenon to lower the temperature than the ambient temperature to prevent tropical night phenomenon and heat island phenomenon in the summer, energy saving Of course, there is an effect that can provide a comfortable environment.

Description

Heat isolathing block or Cool Isolathing block use of the Appearance by Convection and Method OF Producing The same} in the landscaping, park, tourist destination, road, river, construction

The present invention relates to a heat shield or a cooling block using a convection phenomenon installed in a landscaping, a park, a tourist spot, a road, a river, a construction, and a method of manufacturing the same. After forming the layer, by forming the heat shield aggregate layer on the upper surface again, the heat of the high temperature irradiated in summer becomes convective and the temperature of the upper surface of the block is lower than the surrounding temperature, thereby significantly reducing the heat island phenomenon. The present invention relates to a heat shield or a cold block and a method of manufacturing the same so that the temperature is higher than ambient.

As is well known, convection is a phenomenon in which warm air rises up, cold air goes down, warm air cools and cold air warms up.

For example, the air warmed by the high surface temperatures of the land during the summer rises to the sky, and the empty space is filled with low-temperature sea air, which blows the North Pacific summer breeze. On the contrary, in winter, the sea air rises warmer than the land surface of the sea's air temperature, and the winter winds of Siberia blow as the air on the low temperature land is filled to fill the void on the sea side.

In addition, African zebras have white hairs alternately placed on a black skin, so that convection occurs between the hair and the skin, and the zebra's skin is always kept cool.

In particular, the technology using the convection phenomenon can be found in Hanok in Korea, where the air heated by the direct sunlight from the white clay laid out in the front yard moves with the air cooled by the trees in the back yard. Will occur. Therefore, the inside of the hanok is kept cool by the flow of air.

In addition, in the home products, it can be seen that the freezer compartment of the refrigerator is located above the refrigerating compartment. In addition, using the convection phenomenon, the cold air of the freezer compartment goes down to the cold compartment to cool the cold compartment, the hot air of the refrigerator compartment is pushed down the cold air coming down to the freezer compartment to cool again and circulate.

On the other hand, as shown in Figure 1, after mixing the cement, sand and water as shown in Figure 1, and put it in the molding die, and the upper part of the color silica sand by pressing and vibrating, the aggregate layer 10 and the silica sand Molded into two stages of layer 20.

However, such a general block increases the ambient temperature while absorbing and accumulating or reflecting heat when the sunlight of high temperature in summer is irradiated.

Therefore, the heat island phenomenon occurs due to the heat discharged from the block, which causes discomfort to residents and road users, and provides an unhealthy environment.

In addition, in winter, as the upper surface of the block is rapidly cooled, the temperature is lowered and freezing occurs, which may cause reluctance to use by threatening the safety of residents and road users.

The present invention has been made to solve the conventional problems as described above, by using the floor of the park, the floor of the apartment complex, the wall of the building, the air circulating by the convection phenomenon, the temperature of the block upper surface than the ambient temperature in summer It aims to prevent tropical night phenomenon and heat island phenomenon, and to prevent freezing by allowing the temperature of the upper surface of the block to be higher than the ambient temperature in winter, thereby saving energy and providing a pleasant environment.

The present invention is an aggregate layer is formed at the bottom of the coarse aggregate is mixed to achieve the above object; A black pigment layer formed on an upper surface of the aggregate layer to absorb heat; And an upper layer formed on an upper surface of the pigment layer to block heat.

According to another embodiment of the present invention, the aggregate layer is coarse aggregate is formed at the bottom; Black or white pigment layer formed on the upper surface of the aggregate layer; And an upper layer formed on an upper surface of the pigment layer and having a color complementary to the pigment layer.

According to another embodiment of the present invention, the aggregate layer is coarse aggregate is formed at the bottom; Black or white pigment layer formed on the upper surface of the aggregate layer; An upper layer formed on an upper surface of the pigment layer and having a color complementary to the pigment layer; It is formed between the upper layer and the upper layer on the upper surface of the pigment layer, the upper pigment layer of the same color as the pigment layer; characterized in that it comprises a.

According to one embodiment of the invention, the pigment layer is characterized in that the fine aggregate and the pigment paste of black or white is formed by mixing with water.

According to an embodiment of the present invention, the upper layer is characterized in that the pigment layer and the complementary color of one or two or more selected from ceramic, granite, diatomaceous earth, zeolite, earth, ocher are mixed.

According to the heat shield or cold block manufacturing method of the present invention, to 100 parts by weight of the heat shield or cold block, mixing 75 parts by weight of coarse aggregate, 23 parts by weight of mortar and 2 parts by weight of black or white pigment paste; Mixing water by mixing the mixed coarse aggregate with mortar and pigment paste; Forming a pigment layer by pouring the mixed coarse aggregate, mortar and pigment paste into a mold; Forming a top layer by mixing and stacking one or two or more selected from ceramic, granite, diatomaceous earth, zeolite, soil, and ocher in a color complementary to the pigment layer on the pigment layer; And a pressing step of pressing the upper portion while vibrating the molding die.

According to another embodiment of the present invention, a method of manufacturing a heat shield or cold block, the method comprising: mixing 75 parts by weight of coarse aggregate and 25 parts by weight of mortar with respect to 100 parts by weight of the heat shield or cooling block; Mixing water by mixing water with the mixed coarse aggregate and mortar; Forming an aggregate layer by pouring the mixed coarse aggregate and mortar into a mold; Forming a pigment layer by laminating 2 parts by weight of fine aggregate and 2 parts by weight of black or white pigment paste on an upper surface of the aggregate layer poured on the mold; Forming a top layer by mixing and stacking one or two or more selected from ceramic, granite, diatomaceous earth, zeolite, soil, and ocher in a color complementary to the pigment layer on the pigment layer; And a pressing step of pressing the upper portion while vibrating the molding die.

According to another embodiment of the present invention, a method of manufacturing a heat shield or cold block, the method comprising: mixing 75 parts by weight of coarse aggregate and 25 parts by weight of mortar with respect to 100 parts by weight of the heat shield or cooling block; Mixing water by mixing water with the mixed coarse aggregate and mortar; Forming an aggregate layer by pouring the mixed coarse aggregate and mortar into a mold; Forming a pigment layer by laminating 2 parts by weight of fine aggregate and 2 parts by weight of black or white pigment paste on an upper surface of the aggregate layer poured on the mold; Forming a top layer by mixing and stacking one or two or more selected from ceramic, granite, diatomaceous earth, zeolite, soil, and ocher in a pigment layer and a complementary color on an upper surface of the pigment layer; Stacking a pigment paste and fine aggregate having the same color as the pigment layer on the side of the upper layer to form an upper pigment layer; And a pressing step of pressing the upper portion while vibrating the molding die.

The heat shield or cold block of the present invention is used in the floor of a park, the floor of an apartment complex, the wall of a building, etc., while the air is circulated by convection, thereby lowering the temperature of the block upper surface than the ambient temperature in the summer to prevent tropical night phenomenon and heat island phenomenon. In winter, it prevents freezing and saves energy and provides a pleasant environment.

1 is an exemplary view of a general block.
2 is an exemplary view of a heat shield or a cold block according to an embodiment of the present invention.
3 is a side cross-sectional view of a heat shield block according to an embodiment of the present invention.
4 is an exemplary view of a heat shield or a cold block according to another embodiment of the present invention.
5 is a side cross-sectional view of a heat shield block according to another embodiment of the present invention.
6 is an exemplary view of a heat shield or a cold block according to another embodiment of the present invention.
7 is a side cross-sectional view of a heat shield or a cooling block according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the configuration of the most preferred embodiment of the present invention will be described in detail.

Example 1

2 is an exemplary view of a heat shield or a cold block according to an embodiment of the present invention, Figure 3 is a side cross-sectional view of a heat shield block according to an embodiment of the present invention.

The heat shield or cold block of the present invention may be composed of a pigment layer 100 and an upper layer 200.

Pigment layer 100 is made of a mixture of coarse aggregate and mortar and black or white pigment paste. At this time, the pigment layer 100 is preferably formed to have a predetermined thickness to have a predetermined strength.

The upper layer 200 is formed on the upper surface of the pigment layer 100, and is made of any one or a mixture of two or more selected from pores of ceramic, granite, diatomaceous earth, zeolite, soil, and loess. At this time, the upper layer 200 is preferably selected as the color of the pigment layer 100 and the complementary color.

[Example 2]

4 is an exemplary view of a heat shield or a cold block according to another embodiment of the present invention, Figure 5 is a side cross-sectional view of a heat shield block according to another embodiment of the present invention.

The heat shield or the cooling block of the present invention is composed of the pigment layer 100 and the upper layer 200 and the aggregate layer 300 at the bottom of the pigment layer 100.

Aggregate layer 300 is made of a predetermined thickness by mixing the aggregate and mortar of a predetermined thickness or more, the pigment layer 100 is formed on the aggregate layer 300.

Pigment layer 100 is made of a mixture of fine aggregate and black or white pigment paste.

The upper layer 200 is formed on the upper surface of the pigment layer 100, and is made of any one or a mixture of two or more of ceramic, granite, diatomaceous earth, zeolite, soil, and ocher. At this time, the upper layer 200 is preferably selected as the color of the pigment layer 100 and the complementary color.

[Example 3]

6 is an exemplary view of a heat shield or cold block according to another embodiment of the present invention, Figure 7 is a side cross-sectional view of a heat shield or cold block according to another embodiment of the present invention.

According to another embodiment of the present invention, the heat shield or the cooling block includes the upper layer 200 and the upper pigment layer 400, and the pigment layer 100 on the top of the pigment layer 100 and the pigment layer 100. It is composed of the aggregate layer 300 at the bottom.

Aggregate layer 300 is made of a predetermined thickness by mixing the aggregate and mortar of a predetermined thickness or more, the pigment layer 100 is formed on the aggregate layer 300.

Pigment layer 100 is made of a mixture of fine aggregate and pigment paste of black or white.

The upper layer 200 is formed on the upper surface of the pigment layer 100 with a predetermined width, and is made of any one or two or more of ceramics, granite, diatomaceous earth, zeolite, soil, loess having pores. At this time, the upper layer 200 is preferably selected as the color of the pigment layer 100 and the complementary color.

In addition, an upper pigment layer 400 having a predetermined width may be further formed on a side surface of the upper layer 200 such that the upper layer 200 and the upper pigment layer 400 may be repeatedly formed.

The upper pigment layer 400 is preferably made of a mixture of mortar and fine aggregate and black or white pigment paste in the same manner as the pigment layer 100.

Hereinafter, a method and an operation of manufacturing a heat shield or a cold block of the present invention will be described.

With respect to 100 parts by weight of the heat shield or the cold block, 75 parts by weight of the aggregate having a predetermined thickness or more, 23 parts by weight of mortar and 2 parts by weight of pigment paste are mixed with each other, and then an appropriate amount of water is poured and mixed. In this case, the pigment paste is selected from either black or white. That is, in summer, it is preferable to select the color of the pigment paste as black so that the endothermic effect is improved, and in winter, select the color of the pigment paste as a white series to improve the heat shielding effect.

The thick coarse aggregate and the mortar and the black or white pigment paste are poured into a mold to form the pigment layer 100 of the heat shield or the cold block to be molded to a predetermined thickness to have a predetermined strength.

The upper layer 200 is formed on the upper surface of the pigment layer 100 by stacking any one or a mixture of two or more selected from pores such as ceramic, granite, diatomaceous earth, zeolite, soil, and yellow soil.

When the pigment layer 100 and the upper layer 200 are stacked on the molding die, the vibration molding mold is vibrated by a separate vibrating device, and is pressed by a predetermined pressure on the upper side of the molding die by a separate pressurizing device to block heat or cool the block. Form the form of.

In addition, as a method for manufacturing a heat shield or cold block according to another embodiment, 75 parts by weight of aggregate having a predetermined thickness or more and 25 parts by weight of mortar are mixed with 100 parts by weight of the heat shield or cold block, and then poured with an appropriate amount of water. Then, it is poured into a mold to form the aggregate layer 300 of the heat shield or cold block to be molded.

The pigment layer 100 is formed by mixing and stacking 2 parts by weight of fine aggregate and 2 parts by weight of black or white pigment paste on the top surface of the aggregate layer 300.

In addition, the upper layer 200 is formed on the upper surface of the pigment layer 100 by stacking any one or a mixture of two or more selected from pores such as ceramic, granite, diatomaceous earth, zeolite, soil, and ocher. In this case, the upper layer 200 is preferably selected as a color having a complementary color relationship with the pigment layer 100.

That is, in the case of the heat blocking block for lowering the summer temperature, the pigment layer 100 is preferably applied in black and the upper layer 200 is applied in white. In addition, in the case of a cold block for increasing the winter temperature, the pigment layer 100 is preferably applied in white and the upper layer 200 is preferably applied in black.

When the aggregate layer 300, the pigment layer 100, and the upper layer 200 are stacked on the mold, the mold is vibrated by a separate vibrating device, and at a predetermined pressure in the upper part of the mold by a separate pressing device. Pressurizing to form the heat shield or cold block.

Meanwhile, the upper layer 200 is formed by stacking any one or two or more mixtures selected from silica sand, ceramic, diatomaceous earth, zeolite, soil, and ocher with pores on one side of the pigment layer 100, and the upper layer 200. It is also preferable to form the upper pigment layer 400 of the same color as the pigment layer 100 on the side. That is, it is preferable to continuously and repeatedly form the upper layer 200 and the upper pigment layer 400 to the side.

In this case, the upper layer 200 is preferably selected as a color having a complementary color relationship with the pigment layer 100. That is, when the pigment layer 100 is applied in black, the upper layer 200 is preferably applied in white to constitute a heat shield block. When the pigment layer 100 is applied in white, the upper layer 200 is It is preferable to configure the cold cooling block by applying in black.

Therefore, the heat shield or the cold block of the present invention can be constructed by alternately applying the heat shield block or the cold block, or the heat shield block and the cold block to the floor of the park, sidewalk, apartment complex floor, outdoor parking lot floor, building wall.

Therefore, the block top surface is maintained at a lower temperature than the surrounding temperature by the heat blocking block even when the sunlight is irradiated hot in summer, and the temperature of the block top surface is higher than the ambient temperature by the cold block in winter.

That is, in the case of the heat blocking block, a portion of sunlight is blocked by the upper layer 200, and the temperature rise of the upper layer 200 is reduced, and a part of the heat passing through the pores formed in the upper layer 200 is a black pigment layer 100. ) To increase the temperature of the pigment layer 100.

Accordingly, the air of the pigment layer 100 having a high temperature moves to the low temperature air side of the upper upper layer 200 by convection, and the air of the upper layer 200 moves to the lower pigment layer 100. Done.

In addition, in the case of a heat shield block in which the upper layer 200 and the upper pigment layer 400 are repeatedly formed on the upper surface of the pigment layer 100, some of the heat is blocked at the upper layer 200, while the temperature is slightly lowered. In the upper pigment layer 400, the temperature is increased by absorbing heat. Accordingly, the air of the pigment layer 100 is circulated while the air of the pigment layer 100 moves to the upper layer 200 and the air of the upper layer 200 to the pigment layer 100 due to convection, and the air of the upper layer 200 Air of the pigment layer 400 is circulated while moving with each other.

Accordingly, the surface temperature of the general block around midsummer was measured at about 31.3 ° C., while the air was circulated by convection on the block top surface of the park to which the heat blocking block of the present invention was applied, and the surrounding block at about 29.2 ° C. The temperature was measured to be lower than, and the user would feel cooler.

On the other hand, in the case of the cooling block, the upper layer 200 absorbs most of the sunlight, and the pigment layer 100 reflects heat. Therefore, the temperature of the block top surface is higher than the ambient temperature, thereby reducing the occurrence of freezing.

In addition, in the case of the cooling block formed by repeating the upper layer 200 and the upper pigment layer 400 on the upper surface of the pigment layer 100, some of the heat is absorbed by the heat in the upper layer 200 and the temperature is increased. In the upper pigment layer 400, the heat is cut off to lower the temperature. Therefore, the air of the upper layer 200 and the air of the upper pigment layer 400 are circulated while moving with each other due to convection.

While the surface temperature of the general block around midwinter was measured at about 1.7 ° C., it was measured at about 2.6 ° C. higher than the temperature of the surrounding block at the block surface of the park to which the cool block of the present invention was applied.

This prevents freezing of the block surface and reduces cold energy, providing comfort to users walking in parks or apartment complexes, and when applied to the walls of buildings, condensation due to temperature differences between buildings is prevented. Will have an effect.

The foregoing has been described in detail with reference to the drawings to enable those skilled in the art to actually apply an implementation, but it is to be understood that structural, logical and mechanical changes may be made without other implementations being used or departing from the scope of existing implementations. do. In addition, this description is not to be taken in a limiting sense, and the scope of the present invention is defined by the appended claims.

100: pigment layer 200: upper layer
300: aggregate layer 400: upper pigment layer

Claims (8)

Aggregate layer is formed at the bottom of the coarse aggregate is mixed;
Black or white pigment layer formed on the upper surface of the aggregate layer;
An upper layer formed on an upper surface of the pigment layer and having a color complementary to the pigment layer;
And an upper pigment layer formed on an upper surface of the pigment layer between the upper layer and the upper layer, the upper pigment layer having the same color as the pigment layer.
The method of claim 1,
The pigment layer is a heat shield or cold block characterized in that the fine aggregate and black or white pigment paste is formed by mixing with water.
3. The method according to claim 1 or 2,
The upper layer is one or two or more selected from ceramic, granite, diatomaceous earth, zeolite, soil, ocher is mixed, the heat shield or cold block characterized in that the pigment layer and the complementary color.
Mixing 75 parts by weight of coarse aggregate and 25 parts by weight of mortar based on 100 parts by weight of thermal insulation or cold storage block;
Mixing water by mixing water with the mixed coarse aggregate and mortar;
Forming an aggregate layer by pouring the mixed coarse aggregate and mortar into a mold;
Forming a pigment layer by laminating 2 parts by weight of fine aggregate and 2 parts by weight of black or white pigment paste on an upper surface of the aggregate layer poured on the mold;
Forming a top layer by mixing and stacking one or two or more selected from ceramic, granite, diatomaceous earth, zeolite, soil, and ocher in a pigment layer and a complementary color on an upper surface of the pigment layer;
Stacking a pigment paste and fine aggregate having the same color as the pigment layer on the side of the upper layer to form an upper pigment layer; And
Heat shielding or cold block manufacturing method comprising a; pressurizing step from the top while vibrating the mold.
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