KR101998710B1 - Goodeul Assembly - Google Patents

Abstract

The present invention relates to a floor heater assembly using ceramic. More specifically, heat columns are arranged on lower portions of four corners having an obliquely cut shape of an upper plate having a rectangular plate shape and having a middle portion convex upwards to have a heat pocket integrally formed therein. The heat columns and upper plates made of ceramic are continuously arranged. A heat storage material is stacked on the upper plates and in the heat columns, and heat is applied to couple the upper plates and the heat columns to form a floor heater to eliminate corrosion risks. Since a separate coupling member is not used, simple construction is possible. A heat storing space is wide to improve heating effects.

Description

{Goodeul Assembly}

[0001] The present invention relates to a sphere assembly, and more particularly, to a sphere assembly, more specifically a sphere assembly, which is formed in a regular polygonal plate shape and has a central portion convex upwardly and having a heat- The top plate and the heat column made of ceramics are successively arranged and the heat accumulating material is piled up on the inside and the top plate of the heat column and the heat is applied to the top plate and the heat column to form the spheres, The present invention relates to a spherical assembly having a high heating effect due to its wide space for accommodating the heat.

Typically, the heating system of a traditional house is heated by using heat and smoke generated by burning firewood, and then heating the hearth by means of the heat of the hearth.

In addition to the firewood that is used to cut wood, it also uses a variety of combustible materials, such as discarded woods and twigs, that can be obtained in the course of everyday life, as a fuel. .

Generally, the phrases can be guessed from the stones baked with pure Korean. It is the representative heating system of Korea that warms the rooftop by letting fire under the floor.

In the heating structure using the conventional heating facilities such as the conventional heating facilities, the roof structure of Patent No. 10-1177494 has an oven for blowing hot water on one side of the house, and the oven is heated by the hot water flowing through the oven A fire generated from the firebox spreads uniformly along a passage of a whale, which is formed between a plurality of bricks, and the smoke, which has been circulated through the whale, is discharged through a chimney to the outside .

Conventional conventional spheres are complicated in structure, difficult to construct, and take a long time to work.

In addition, in the conventional spheres, all the whales are concentrated in the lower part (middle part) and middle part of the room, and the lower part is excessively hot. The edges (side) and the upper part of the room are relatively cold. There is a problem that it takes a long time to heat up.

In order to solve this problem, the inventor of the present invention has invented a structure of the Korean Patent No. 10-1775465 and the structure of the assembly of the Korean Patent Application No. 10-2017-0081441, The entire floor is uniformly heated, and the heating is performed quickly. However, since the construction is made of an iron plate and has a large number of constitutions for joining, the construction is complicated and the construction process is prolonged by using a separate screw or cement, The space for storing heat in the heat transfer support for transferring the heat to the heat storage material is narrow and is formed as a thin steel plate as a whole, so that the effect of holding the heat is reduced and corrosion may be caused.

KR 10-1177494 (registration number) 2012.08.21. KR 10-1775465 (registration number) 2017.08.31. KR10-2017-0081441 (application number) 2017.06.27.

Accordingly, the present invention has been made to solve the above problems,

The heat plate is formed integrally with the upper plate and the upper plate and the heat column are combined with the heat plate by placing the heat accumulating material on the upper and lower opened columns disposed below the upper plate vertex, And which has a large space for holding the heat and has a large contact area with the heat storage material, thereby achieving a rapid heating effect.

Another object of the present invention is to arrange a column at a lower portion of a vertex obliquely cut in an upper plate having a square plate shape and a center portion convex upwardly and having a heat pocket formed therein, The columns are continuously arranged and the heat accumulating material is stacked on the inside of the column and the top plate to form the sills to pass the heat to the lower portion of the top plate so that the height of the corner of the top plate on the column is higher than the center of the top plate between the columns The heat accumulating material contained in the column is filled with the heat accumulating material from the column to the floor so that a certain portion of the upper part of the column is covered by the upper part of the column while heating takes a lot of time, And this heat is transferred to the heat storage material on the top plate, Ex This is to quickly provide phrases assembly capable of heating the heat storage material increases.

It is a further object of the present invention to provide a method of manufacturing a semiconductor device, the method comprising: forming vertices of an upper plate contacting a thermal column to be thicker than a central portion, or forming a rim including a vertex to be thicker than a central portion, Assembly.

It is still another object of the present invention to provide a socket assembly which can form a position groove on an upper column of a thermal column to make it easier to locate and locate the position groove when mounting the upper plate, and to uniformly install the same.

Another object of the present invention is to provide a multi-stage heat accumulating device in which two or more heat piles are stacked to form a multi-stage heat pipe when the floor height varies according to a construction environment, When the lower column that is narrower than the upper column is inserted into the upper column, the space between the upper column of the lower column and the lower column of the upper column, which is wider than the upper column, And a height adjustable spherical assembly.

To achieve the above object, according to the present invention, there is provided an image forming apparatus, comprising: an upper plate (110) having a central portion (111) convex upwardly and having a heat pocket (111a) formed therein and a vertex portion (112) The upper column 121 is disposed below the vertex portion 112 of the upper plate 110 and has a width greater than that of the upper column 121, A plurality of top plates 110 and a plurality of column columns 120 are continuously arranged and arranged in a lower column 122 in which the step 122a is formed, Being; The thermal storage material 200 is lowered and accumulated in the thermal column 120 and the thermal storage material 200 is piled up on the upper plate 110 so that the thermal storage material 200 on the upper part of the thermal column 120 and the upper plate 110, Are connected to each other; The height of the heat storage material 200 on the central part 111 of the upper plate 110 is smaller than the height of the heat storage material 200 on the upper part of the heat column 120, Repeated; Heat is passed to the lower portion of the upper plate 110.

The upper plate 110 is formed such that the rim 113 extending from the vertex 112 is thicker than the central portion 111.

The upper column 121 of the column 120 has a plurality of positioning grooves 121a spaced apart from each other by a predetermined distance when the upper plate 110 is disposed.

The upper column 121 of the thermal column 120 is inclined so as to be wider as it goes down. The lower column 122 is higher than the upper column 121.

When the heat accumulating material 200 is inserted into the multi-stage multi-stage heat accumulating material 120, at least two of the plurality of heat accumulating materials 120 are stacked, 121 and the lower column 122 of the heat column 120 located at the upper part of the heat accumulating member 200, the height of the heat accumulating member 200 is adjusted.

The vertex 112 of the top plate 110 is arranged to occupy a space on the top of the column 120 so that the top of the column 120 without the top plate 110 is open.

The lower surface of the vertex portion 112 is formed in a flat plate shape, and the flat plate is in line contact with the upper portion of the column 120.

The top plate 110 and the column 120 are formed of ceramics.

The area of the central portion 111 is larger than the sum of areas of the vertex portion 112 and the rim portion 113.

Therefore, the spherical assembly of the present invention includes a top plate integrally formed with a heat pocket, and a heat accumulating member disposed above the upper and lower opened heat columns disposed below the top plate vertex, By forming the spheres, there is no risk of corrosion, a simple construction can be made without using a separate joining member, a space for accommodating the heat is large, and a contact area with the heat storage material is large, resulting in rapid heating effect.

The spherical assembly of the present invention has a quadrangular plate shape, and a column is arranged at a lower portion of a vertex obliquely cut away from an upper plate having a central portion convex upwardly and a heat pocket formed therein, The columns are continuously arranged and the heat accumulating material is stacked on the inside of the column and the top plate to form the sills to pass the heat to the lower portion of the top plate so that the height of the corner of the top plate on the column is higher than the center of the top plate between the columns The heat accumulating material contained in the column is filled with the heat accumulating material from the column to the floor so that a certain portion of the upper part of the column is covered by the upper part of the column while heating takes a lot of time, And this heat is transferred to the heat storage material on the upper plate, There is an effect that can be heated more quickly heat storage material is exposed.

The spherical assembly of the present invention is advantageous in that a positioning groove is formed in the upper column of the column to facilitate positioning of the upper plate when positioning the upper plate, and uniform positioning.

The spherical assembly of the present invention has a position groove on an upper column of a column to facilitate positioning of the upper plate when positioning the upper plate, and uniform positioning is possible.

When the height of the bottom of the spherical assembly according to the present invention is changed according to the construction environment, two or more heat poles are stacked to form a multi-tier, and when the heat storage material is inserted into the multi-tiered heat pillar, When the lower column, which is narrower than the upper column, is inserted into the upper column, the space between the upper column of the lower column and the lower column of the column located at the lower part is tightly coupled to the upper column. There is a possible effect.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a ball screw assembly according to an embodiment of the present invention,
FIG. 2 is a perspective view of a top plate and an open end of a spherical assembly according to an embodiment of the present invention,
3 is a plan view of a spherical assembly according to an embodiment of the present invention,
FIG. 4 is a perspective view of a mold assembly according to an exemplary embodiment of the present invention,
5 is a cross-sectional view of a state in which a spherical assembly according to an embodiment of the present invention is installed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

 The spherical assembly 100 according to the present invention is formed on the bottom surface of a floor provided with an oven to form spheres. The spherical assembly 100 has a rectangular plate shape as shown in FIGS. 1 to 5, An upper plate 110 having a heat pocket 111a on the inner side and an upper surface of the four vertexes being obliquely cut,

An upper pillar 121 disposed below the vertex portion 112 and thicker than the central portion 111 of the upper plate 110 and inclined so as to be wider toward the lower portion; And a thermal column 120 formed of a lower column 122 having a wide and high height and a step 122a formed between the upper column 121 and the upper column 121,

A plurality of top plates 110 and heat columns 120 are successively arranged,

The heat storage material 200 is stacked on the upper and lower columns 110 and 110 so that the heat is transmitted to the lower portion of the upper plate 110 and the heat of the chamber is transmitted to the upper plate 110 and the column 120 So as to form spheres for heating the floor through the heat storage material 200.

The top plate 110 is preferably made of a square having four sides of the same length, but it is not limited thereto and a regular polygonal shape such as an equilateral triangle, a regular pentagon, and a regular hexagon is also possible. The top plate 110 of the present invention is shown and described on the basis of a square shape. The upper plate 110 has a central portion 111 rising upwardly and convexly and formed as a hollow space inwardly of the lower portion to provide a space for storing heat generated in an oven (not shown) 111a. Accordingly, the top plate 110 is integrally formed with a heat-conducting bag 111a whose lower edge is lower than the center, and whose lower inner side is convexly protruded.

The central portion 111 occupies most of the area of the top plate 110 excluding the four corner portions 112 and the rim portion 113. The area of the heat storage bag 111a, So as to be firmly formed. The central part 111 is rounded and protruded upward. The heat storage material 200 is accumulated on the central part 111, and a floor is completed through a finishing material (not shown). The floor is a place where people live and various living furniture is placed, and a considerable weight is generated in the upper part. Since the weight is supported by the top plate 110 and the column 120, the top plate 110 should be rigid and free of weight damage. Since the central portion 111 of the top plate 110 of the present invention protrudes so as to be rounded upward, the supporting force against the weight is stronger than that of the flat plate. At the same time, the top plate 110 is heated near the floor at the center point, It keeps the heat of the oven and keeps it on the sides and top.

Thus, the top plate 110 performs robustness to weight and fast and stable heat transfer to the floor.

The spherical assembly 100 according to the present invention has a structure in which the spherical structure previously formed by the present inventor has a narrow heat pocket and is made of an iron plate, By enlarging the area and making it with ceramics, the heating effect is enhanced and durability is improved.

The vertex portion 112 of the upper plate 110 is thicker than the central portion 111 and the column 120 is disposed at the lower portion. Since the vertex portion 112 is fixed in line contact with the column 120 supporting the entire upper plate 110, the vertex portion 112 must be sufficiently rigid to support the weight of the floor so that its thickness is thicker than the central portion 111 . In addition, since the center portion 111 must transfer the heat transferred to the furnace to the heat storage material, its thickness can not be increased.

The vertex portion 112 is a supporting portion on which the column 120 is disposed.

The four vertexes 112 of the top plate 110 are formed in such a manner that the upper surface thereof is obliquely scored, and can be smoothly rounded in a curved line or straightened in a straight line. In addition, the lower surface of the four vertexes 112 is formed in a flat plane and is linearly contact-coupled with the column 120 in a stable manner.

The lower surface of the upper plate 110 is flat on the vertex portion 112 and rises upwardly from a portion corresponding to the central portion 111 to form a depression and the central portion 111 becomes circular.

When the heat accumulating material is placed on the upper part of the column 120, the part is covered by the four vertexes 112 and the remaining part is opened, and is inserted into the column 120 through the open space . Therefore, if the end surface of the rim portion 113 of the top plate 110 continues to be straight, there is no space open at the top of the column so that the heat storage material can not be inserted.

The four vertexes 112 of the top plate 110 are obliquely cut so that when the heat storage material 200 is stacked on the top plate 110, So that the heat storage material 200 can be directly inserted thereinto.

A corner portion extending from the vertex portion 112 and a peripheral portion 113 surrounding the vertex portion 112 are provided between the vertex portion 112 and the vertex portion 112 in the upper plate 110, And the upper plate 110 may be stably supported on the column 120 by a thickness equal to or smaller than that of the column 112.

The top plate 110 is formed in a straight line in a cross section of the rim 113 and is in close contact with the other top plate 110 which is in contact with the four sides of the top plate 110 without being separated.

When the top plate 110 and the other top plate 110 are in contact with each other, the heat storage material 200 is stacked and heated without using cement or other joining members. That is, the heat storage material is hardened by the heat supplied from the furnace, and the inside of the heat column 120 and the top plate 110 are integrally formed, so they are firmly fixed to each other without any artificial adhesive element such as cement.

Heat and smoke generated in the oven are transferred to the lower part of the upper plate 110, but the smoke is not discharged to the other upper plate 110 in contact with the upper plate 110.

The thermal column 120 is disposed below the vertex portion 112 of the upper plate 110. When one upper plate 110 divides the upper column 121 of the column 120 into four equal parts, And four top plates 110 are seated on the one column 120 and one vertex 112 is seated on the four top plates 110.

In order to seat the upper plate 110 on a surface corresponding to a quarter of the upper surface of the upper column 121 of the thermal column 120, the upper column 121 of the thermal column 120 is formed in a cross shape The position groove 121a is formed in the four positions of the top plate 110 and the top plate 110. When the top plate 110 is placed on the top plate 110, the top plate 112 of the top plate 110 is aligned with the position groove 121a, Respectively.

The heat column 120 is composed of an upper column 121 provided at the upper part and an upper column 121 provided at the upper part and a lower column 122 provided at the lower part. (A) of the lower column 122 is lower than the height (b) of the lower column 122.

The upper column 121 is slightly inclined inward so that the width of the upper column 121 becomes narrower toward the upper side. When the column columns 120 are stacked in two stages, the lower column 122 of the upper column 120 And is inserted between the upper column 121 of the lower column 120 and the lower column 122 of the upper column 120 at the upper portion of the lower column 121 A spaced space is generated.

The lower column 122 has a width greater than that of the upper column 121 and is formed to have a constant width so that a step 122a is formed on an outer circumferential surface of the lower column 122, The overlapping lower pillars 122 are seated.

When the heat storage material 200 is inserted into the upper heat storage column 120 when the upper heat storage material 121 is formed by stacking the heat storage columns 120 in two or more stages, The heat storage material 200 is inserted into the space between the upper column 121 of the lower column 120 and the lower column 122 of the upper column 120 at the upper part. They are hardened by heat and are made to be coupled to each other.

Since the heat storage material 200 is inserted between the upper column 120 and the lower column 120 and the heat storage material 200 is inserted at a fixed height to fix the upper and lower openings, And is adjustably provided.

The heat storage material 200 inserted in the heat column 120 is located in a heat transfer passage through which heat is transferred and is directly heated in the oven, The heat is transferred to the top plate 110 and the heat accumulating material accumulated continuously, so that the heat is transferred quickly.

The heat storage material 200 is in the form of powder or paste and enters the inside of the heat column 120 to heat the heat column 120 and the upper plate 110 firmly to the floor do.

The heat storage material 200 may be entirely kneaded or the upper portion may be formed by dough and the upper portion (floor surface) may be treated with a finish material such as a long plate.

The heat storage material 200 is built in the upper part of the upper plate 110 and the heat column 120 to store heat generated in the furnace.

The heat storage material 200 is thick in the lower part and thinner in thickness from the upper part. With this effect, a long time is required for the floor of the lower part to become hot, but the lower part can receive strong heat directly from the fire Rather, the floor is not over heated.

In addition, since the storage material 200 in the lower portion is thick, the heat storage material 200 that has accumulated heat can store warm heat for a long time, thereby enabling to enjoy a long-time warming effect.

Since the top portion of the heat storage material 200 has a small thickness, the time for transferring heat to the floor is short, but it is far away from the furnace and can be heated at a speed similar to that of the bottom portion.

The thickness of the bottom and top of the heat storage material 200 is determined so that the finishing material (corresponding to the floor of the room) on the heat storage material 200 is uniformly heated according to the width of the entire floor and the length from the bottom to the top.

The heat storage material 200 may be made of yellow soil, gravel, sand, elvan, jade, charcoal, etc., alone or in combination. The finishing material (not shown) on the upper side of the heat storage material 200 corresponds to the floor and is made of a material suitable for dwelling, such as an elvan plate, an ondol, a marble, an oak plate,

If the height of the upper plate 110 is changed due to a non-uniform bottom surface or a difference in space between the heat transfer passages, two or more thermal columns 120 may be stacked as shown in FIG. And the upper plate 110 is disposed on the upper part of the column 120.

As described above, the sphere assembly 100 is installed in a room with an oven, and bricks are piled on the inner side of the room to prevent smoke from leaking to the outside, and the heat storage material 200 is stacked on the bricks, Respectively.

The sphere assembly 100 includes a lower portion of the upper plate 110 and a space in which the heat column 120 is formed. The sill assembly 100 includes a heat transfer passage through which heat generated by the furnace and smoke flows. It is preferable to form a chimney in the room for installation so that the smoke is discharged outside.

The combination of the upper plate 110 and the upper plate 110 and the combination of the upper plate 110 and the column 120 may be achieved by the heat storage material 200 provided on the upper plate 110, It becomes hard and hard.

The spherical assembly 100 according to the present invention serves to heat the top plate 110 itself, which is made up of a ball, to provide a large space for heating the ball.

The heat accumulating material 200 disposed on the upper part of the spherical assembly 100 is hardened by the heat of the oven and the heat pillar 120 and the upper plate 110 are integrally coupled with each other, The heat storage material serves as a column for supporting the upper plate 110 as a whole, and the upper plate and the heat storage material are integrally connected to each other, so that they are formed firmly and firmly so as to receive heat from the furnace.

The sphere assembly 100 according to the present invention includes a top plate 110 having a heat bag 111a formed integrally therewith and an upper and lower openings The heat storage material 200 is piled up on the column 120 and heat is applied to form the upper plate 110 and the column 120 together to form the spheres so that there is no risk of corrosion, And the space for holding the heat is wide, so that it is possible to heat quickly and quickly.

The spherical assembly 100 according to the present invention includes a top plate 110 having a center portion 111 convex upward and having a heat pocket 111a formed therein and four vertexes A plurality of top plates 110 and a plurality of heat columns 120 are continuously disposed and a heat storage material 200 is disposed on the top and bottom plates 110 and 110 The height of the vertex portion 112 of the top plate 110 on the column 120 is greater than the height of the top plate 110 between the columns 120. [ A certain amount of the heat accumulating material 200 enters from the heat column 120 to the floor and the heating time becomes long. However, since a certain portion of the upper portion of the heat column 120 is separated from the upper plate 110, The thermal storage material 200 embedded in the thermal column 120 may be formed so as to cover the vertex portion 112 of the furnace, Received is hot, the heat is transmitted to the top plate 110, the heat storage material 200 in the above without resistance there is an effect that it is possible to heat the heat storage material quickly 200 more than the other exposed to the open position.

The spherical assembly 100 of the present invention may be configured such that the vertex 112 of the top plate 110 contacting the column 120 is thicker than the center 111 or the edge 113 including the vertex 112 The heat column 120 can stably support the top plate 110 by forming the groove 121a in the upper column 121 of the heat column 120, The positioning groove 121a can be easily seen and centered, and uniform construction can be achieved.

When the height of the floor changes according to a construction environment, the spherical assembly 100 of the present invention may be formed by stacking two or more heat pillar 120 in a multi-stage manner, and the heat storage material 200 is inserted into the multi- When the upper column 121 of the thermal column 120 is inserted into the upper column 121, the lower column 122 having a width narrower as the upper column 121 is inserted into the upper column 121 becomes narrower than the upper column 121, The heat storage material 200 is firmly inserted into the spaces between the upper pillars 121 of the pillars 120 and the lower pillars 122 of the upper pillars 120 and the height of the pillars can be adjusted.

100:
110: top plate 111: center
111a: heat pocket 112: vertex portion
113:
120: column 121: upper column
121a: Position groove 122: Lower column
122a: step
200: Heat storage material

Claims (9)

An upper plate 110 having a center portion 111 convex upwardly and having a heat pocket 111a formed on the inside thereof and a vertex portion 112 formed in a shape of being cut;
The upper column 121 is disposed below the vertex portion 112 of the upper plate 110 and has a width greater than that of the upper column 121, And a columnar column 120 formed by the lower column 122 in which the step 122a is formed and the upper and lower openings are opened,
A plurality of top plates 110 and column posts 120 are successively disposed;
The thermal storage material 200 is lowered and accumulated in the thermal column 120 and the thermal storage material 200 is piled up on the upper plate 110 so that the thermal storage material 200 on the upper part of the thermal column 120 and the upper plate 110, Are connected to each other;
The height of the heat storage material 200 on the central part 111 of the upper plate 110 is smaller than the height of the heat storage material 200 on the upper part of the heat column 120, Repeated;
And heat is passed to the lower portion of the upper plate (110).
The method according to claim 1,
Wherein the top plate (110) has a rim (113) extending from the vertex (112) to a greater thickness than the center (111).
The method according to claim 1,
The upper column (121) of the thermal column (120) is provided with position grooves (121a) spaced apart from each other by a predetermined distance in order to position the upper plate (110).
The method according to claim 1,
The upper column 121 of the column 120 is inclined so as to be wider as it goes down,
Wherein the lower column (122) is higher than the upper column (121).
5. The method of claim 4,
When two or more thermal columns 120 are stacked and formed into a multi-stage structure and the heat storage material 200 is inserted into the multi-stage heat column 120, And the heat storage material (200) is inserted into the spaced space between the upper column (120) and the lower column (122) of the upper column (120).
The method according to claim 1,
Wherein the vertex portion 112 of the top plate 110 is disposed to occupy some space above the column 120 so that the top portion of the column 120 without the top plate 110 is open.
delete The method according to claim 1,
Wherein the top plate (110) and the column (120) are formed of ceramics.
3. The method of claim 2,
Wherein an area of the central portion (111) is greater than a sum of the areas of the vertex portion (112) and the rim portion (113).

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