KR100418963B1 - A prefabrication loess panel - Google Patents

Abstract

The present invention relates to a prefabricated ocher panel and a method for manufacturing the same, which are poured on both sides, and one side of which is thicker than the other side; A plurality of distribution holes for circulating air to both sides of the loess, and a heat insulator having a buried material embedded in the distribution holes to emit far infrared rays; A friction layer applied to a surface of the heat insulating material to a predetermined thickness to radiate far infrared rays; Consists of a steel wire plated with a rough surface, iron pieces fixedly fixed to the iron wire, steel pins fixed or fixed to the iron wire at fixed intervals, and fixing pins formed with a plurality of protrusions. The high surface friction coefficient is shown by the iron core that is roughly plated, the iron pieces formed at regular intervals on the iron core, and the stone layer formed on the surface of the heat insulating material. Thus, the loess can be firmly adhered to the heat insulating material and the mold. By allowing the air to flow to both sides of the ocher through a distribution hole formed in the heat insulating material, it is possible to balance the temperature and humidity of both sides of the ocher.

Description

Prefabricated loess panel and its manufacturing method {A prefabrication loess panel}

The present invention relates to a prefabricated panel, and more particularly, to form a mold so that the loess is firmly adhered to the heat insulator, through which the air flows between both sides of the ocher, radiating far-infrared rays beneficial to the human body It relates to a prefabricated ocher panel and a method of manufacturing the same.

In general, prefabricated panels are used as structures of walls and roofs of all buildings such as houses, shopping malls, factories, schools, and other neighborhood living facilities, and are used for maintenance of steel frames, interior and exterior wall partitions of concrete buildings, and wall insulation of existing buildings. It is a building material used.

Conventional prefabricated panel is composed of a heat insulating material for insulating, soundproofing, moisture-proof inside and outside, a mold inserted and fixed so as to form the same distance on both sides of the heat insulating material, and cement mortar adhered to the mold.

The mold welds steel wires perpendicularly to a vertical and horizontal grid, and welds a plurality of steel pins at regular intervals vertically to the steel wires forming the grid, and at both ends of the grid, a net or the welded steel pins obliquely. It consists of a mesh form.

Recently, environmentally friendly houses have been proposed and constructed by combining the natural environment and ergonomics, not just a simple functional concept that a home is a space for people to live in. For example, soil is used as an interior and exterior material. So-called ocher houses are being provided.

However, such ocher houses need to make a certain size of blocks by kneading the ocher, and to stack them to a certain height like general concrete blocks, which not only requires a lot of labor time and manpower, but also reduces productivity and costs. do.

Therefore, in order to reduce the productivity and cost, when the ocher is adhered to the conventional prefabricated panel configured as described above, the steel pins forming the mold are smoothly plated on the surface thereof, so that the surface friction coefficient is low, so that the loess is firmly attached to the mold. There is a problem that it does not stick.

In particular, when the loess is adhered between the lattice, there is a problem that the loess is not firmly adhered to the insulating material because the friction coefficient of the insulating material surface is low.

The present invention has been made in view of the above-described problems, the object of which is to form a mold so that the ocher can adhere to the heat insulator, improve the coefficient of friction of the mold so that the ocher can be firmly adhered to the mold It is to.

Still another object is to allow air to flow between the loess on both sides through the insulation and to emit a certain amount of far-infrared rays, which is beneficial to the human body.

1 is a block diagram showing a manufacturing process of a prefabricated ocher panel according to an embodiment of the present invention.

Figure 2 is a perspective view showing a prefabricated ocher panel according to an embodiment of the present invention.

3 is a cross-sectional view of the prefabricated ocher panel.

* Description of the symbols for the main parts of the drawings *

10: ocher 20: insulation

21: distributor 22: landfill

30: friction layer 40: mold

41: iron wire 42: iron piece

43: steel pin 44: fixed pin

Prefabricated ocher panel manufacturing method of the present invention for achieving the above object is made as follows.

To increase the surface friction coefficient, the surface is roughly plated, and between the vertically and horizontally lattices of the steel wires formed with iron pieces at regular intervals, and the molds and fixings for manufacturing the fixing pins formed with a plurality of protrusions. Pin fabrication process;

A distribution hole drilling step of forming a distribution hole by drilling a heat insulating material inserted into both sides of the loess;

A distribution hole embedding process of crushing a landfill material such as charcoal, ganban stone, germanium, etc. emitting far infrared rays into a predetermined size, and burying it in a distribution hole;

A stone coating process of forming a friction layer by applying charcoal, elvan, germanium, and the like, which are crushed to a predetermined size, to a surface of one side of the heat insulating material;

A mold assembly process of inserting a plurality of steel pins into a heat insulating material to assemble one side space between the heat insulating material and the mold to be larger than the other space, and inserting a fixing pin between the molds to assemble the protrusion of the fixing pins;

The kneaded ocher is poured on both sides of the heat insulator and dried so that the ocher on both sides is firmly adhered by the mold and the fixing pin, and one side of the ocher is thicker than the other loess by the gap formed between the heat insulator and the ocher. Ocher casting process;

Characterized in that consists of.

Another configuration of the present invention for achieving the above object is made as follows.

In the prefabricated ocher panel used as the structure of the building wall,

Ocher is poured on both sides, one side is thicker than the other side;

A plurality of distribution holes for circulating air to both sides of the loess, and a heat insulator having a buried material embedded in the distribution holes to emit far infrared rays;

A friction layer applied to a surface of the heat insulating material to a predetermined thickness to radiate far infrared rays;

A mold formed with an iron wire whose surface is roughly plated, an iron piece fixedly fixed to the iron wire at a predetermined interval, a steel pin fixed to the iron wire at a vertical or constant inclination, and a fixing pin having a plurality of protrusions;

Characterized in that consists of.

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

1 is a block diagram showing a manufacturing process of a prefabricated ocher panel according to an embodiment of the present invention.

Figure 2 is a perspective view showing a prefabricated ocher panel according to an embodiment of the present invention.

3 is a cross-sectional view of the prefabricated ocher panel.

Referring to Figure 1, the method of manufacturing a prefabricated ocher panel of the present invention is a mold and a fixed pin manufacturing process (M), a hole drilling process (P), a distribution hole embedding process (I), stone coating process (F) and , Mold assembly step (A), and loess pouring step (C).

Mold and Fixing Pin Manufacturing Process (M)

The steel wire 41 having a high surface friction coefficient is welded at right angles to a vertical and horizontal lattice, and the plurality of steel pins 43 inserted into the heat insulator 20 are perpendicular to the iron wire 41, and the wire 41 The right and left both ends of the) and the net or reticulated mold 40 welded obliquely, and the fixing pin 43 is formed with a plurality of projections.

The iron wire 41 is roughly plated on the surface in order to increase the surface friction coefficient, and forms the iron pieces 42 at regular intervals.

Distribution hole drilling process (P)

Perforating the insulating material 20 inserted into both sides of the loess to distribute the air to both sides of the loess to form a distribution hole 21 for controlling temperature, humidity and the like.

Distribution hole landfill process (I)

The landfill material 22, such as charcoal, elvan, germanium, and the like, which emits far infrared rays, is crushed to a predetermined size and stacked in a distribution hole 21 formed in the heat insulator 20 to be embedded.

Stone coating process (F)

Stones, such as charcoal, elvan, germanium, and the like, which radiate the far circle, are crushed to a certain size, and the crushed stone is sprayed or applied to a surface of one side of the heat insulator 20 to a predetermined thickness to form a friction layer 30.

Of course, not only one surface of the heat insulating material 20 but also may be applied to a predetermined thickness on both surfaces.

Mold assembly process (A)

A plurality of steel pins 43 are inserted to penetrate a predetermined distance between both surfaces of the heat insulating material 20 and the mold 40, and one side space between the heat insulating material 20 and the mold 40 is larger than the other distance. Assemble

In addition, a plurality of fixing pins 44 having protrusions formed between the molds 40 assembled to the heat insulating material 20 are inserted at a predetermined interval and a predetermined length so that the protrusions protrude to the surface of the heat insulating material 20. Assemble as much as possible.

Of course, the protrusion length of the protrusion may be adjusted according to the gap formed between the mold 40 and the heat insulator 20.

Ocher casting process (C)

The mold 40 formed on both sides of the heat insulator 20 and the loess 10 kneaded by the fixing pin 44 are poured and dried.

At this time, the ocher 10 is firmly fixed by the mold 40 and the fixing pin 44, the loess 10 of one side by the interval formed between the heat insulating material 20 and the mold 40 is It adheres thicker than the ocher 10 on the other side.

Prefabricated ocher panel of the present invention manufactured as described above is inserted between the two sides of the ocher 10 and the two sides of the ocher 10, as shown in FIG. 2 and the heat insulating material 20 to insulate, soundproof, moistureproof inside and outside, and the The friction layer 30 formed on one side of the heat insulator 20 and the mold 40 is inserted between the ocher 10 and the heat insulator 20 to fix the ocher 10.

The heat insulating material 20 forms a plurality of distribution holes 21 for circulating air on both sides, and a buried material 22 which is stacked and embedded in the distribution holes 21.

As the buried material 22, it is preferable to use a far-infrared radiator such as charcoal, elvan, germanium, and the like, and other raw materials beneficial to the human body may be used.

The friction layer 30 is applied to the surface of the heat insulating material 20 to a predetermined thickness to increase the surface friction coefficient of the heat insulating material 20 so that the loess 10 is firmly adhered to the surface of the heat insulating material 20.

The friction layer 30 preferably uses a far-infrared radiator such as char, crushed stone, germanium, or the like.

The mold 40 has an iron wire 41 whose surface is roughly plated to increase the coefficient of friction, an iron piece 42 fixedly fixed to the iron wire 41 at a predetermined interval, and a vertical or constant slope to the iron wire 41. Steel pins 43 to be fixed and a plurality of fixing pins 44 are formed is formed.

The wire 41 is preferably welded at right angles to a vertical, horizontal grid to form a net or reticulated shape. The steel pin 43 is perpendicular to the wire 41 formed at the edge of the mold 40. It is preferably welded to, the left and right sides of the mold 40 is preferably welded obliquely to have a certain inclination, the fixing pin 44 is in various forms to securely fix the loess 10 to the heat insulating material (20). It is preferable to produce.

The operation and effects of the present invention as described above will be described with reference to FIGS. 2 to 3 as follows.

As shown in FIG. 2, the iron pieces 42 are formed at regular intervals on the iron wire 41 roughly plated on the surface, and the iron wire 41 is welded at right angles to a vertical and horizontal grid to form a net or reticulated shape 40 ) And a fixing pin 44 having a plurality of protrusions inserted between the mold 40.

Therefore, the loess 10 is firmly adhered to the mold 40 by the iron wire 41 whose surface is roughly plated, and the iron pieces 42 formed at regular intervals on the iron wire 41. Improves its durability.

Thereafter, the insulating material 20 is drilled to form a distribution hole 21, and the landfill material 22, such as charcoal, ganban stone and germanium, is crushed to a predetermined size and embedded in the distribution hole 21, and the charcoal and ganban stone , Crushed germanium, etc. to a predetermined size and applied to one surface of the heat insulating material 20 to a predetermined thickness to form a friction layer (30).

Therefore, the heat insulator 20 exhibits a high surface friction coefficient by the friction layer 30 formed on the surface, and the friction layer 30 makes the loess 10 to be poured firmly adhered to the surface of the heat insulator 20. do.

The distribution hole 21 controls the temperature and humidity of both sides of the ocher 10 in a balanced manner by allowing air to flow to both sides of the ocher 10 which are attached to both sides of the heat insulating material 20 to a predetermined thickness.

In particular, the buried material 22 or the friction layer 30 buried in the distribution hole 21 can release far infrared rays beneficial to the human body to prevent and treat various diseases.

In addition, the ocher 10 is one side of the ocher 10 by the interval formed between the heat insulating material 20 and the mold 40 is thicker than the ocher 10 of the other side, one side of the thickly adhered By making it indoor, it maximizes the insulation and sound insulation effect and reduces the production cost.

As described above, the present invention exhibits a high surface friction coefficient due to the iron core having the surface roughly plated, the iron pieces formed at regular intervals on the iron core, and the friction layer formed on the surface of the heat insulating material. It can stick firmly to the mold.

In addition, by allowing the air to flow to both sides of the ocher through a distribution hole formed in the heat insulating material to adjust the temperature and humidity on both sides of the ocher in a balanced manner.

In particular, various diseases can be prevented by releasing large amounts of far-infrared rays, which are beneficial to the human body, by the friction layer formed on the surface of the buried material and the heat insulating material embedded in the distribution hole.

Claims (2)

In order to increase the surface friction coefficient, the surface 40 is roughly plated, and the mold 40 in which the iron wires 41 having the iron pieces 42 formed at regular intervals are welded at right angles to a vertical and horizontal lattice, and a plurality of protrusions are fixed. A mold and a fixing pin manufacturing process (M) for manufacturing the pin 44; A distribution hole drilling process (P) for forming a distribution hole 21 by drilling the heat insulating material 20 inserted into both sides of the loess 10; A distribution hole embedding process (I) for crushing the landfill material 22 such as charcoal, ganban stone, germanium, etc., emitting far infrared rays to a predetermined size and burying it in the distribution hole 21; A stone coating process (F) for forming a friction layer 30 by applying charcoal, elvan, germanium, and the like, which are crushed to a predetermined size, on the surface of the heat insulating material; A plurality of steel pins 43 are inserted into the heat insulator 20 so that one side space between the heat insulator 20 and the mold 40 is larger than the other side space, and the fixing pin 44 is interposed between the molds 40. A mold assembly process (A) for inserting and assembling the protrusions of the fixing pins 44 to protrude; The kneaded ocher 10 is poured and dried on both sides of the heat insulator 20 so that the ocher on both sides is firmly adhered by the mold 40 and the fixing pin 44, and the heat insulator 20 and the ocher 10 are fixed. Ocher placing process (C) so that one side of the ocher 10 is thicker than the other ocher 10 by the interval formed between the ocher 10; Prefabricated ocher panel manufacturing method characterized in that consisting of. In the prefabricated ocher panel used as the structure of the building wall, Ocher 10 is poured on both sides, one side is thicker than the other side; A heat insulator 20 having a plurality of distribution holes 21 for circulating air to both sides of the ocher 10 and a buried material 22 embedded in the distribution hole 20 to emit far infrared rays; A friction layer 30 applied to a surface of the heat insulating material 20 to a predetermined thickness to radiate far infrared rays; The iron wire 41 is roughly plated on the surface, the iron piece 42 is fixed to the iron wire 41 at a predetermined interval, the steel pin 43 is fixed to the iron wire 41 in a vertical or constant slope, A mold 40 having a fixing pin 44 on which a plurality of protrusions are formed; Prefabricated ocher panel, characterized in that consisting of.