KR101877200B1 - Window frame with improved heat insulation property - Google Patents

Abstract

The present invention relates to a window frame with improved heat insulation, which comprises: an outer frame having a stainless material and formed in a square hollow pipe type, in which an insertion hole is penetrated into a center portion thereof; and a heat insulation assembly forcibly inserted into the insertion hole of the outer frame. Accordingly, the window frame has a stainless-based material and maximizes efficiency of heat insulation while simply coupling members for the heat insulation.

Description

{Window frame with improved heat insulation property}

The present invention relates to a window frame having improved heat insulation. More particularly, the present invention relates to an outer frame which is made of a stainless steel material and has a hollow rectangular pipe shape with an insertion hole formed at the center thereof, The present invention relates to a window frame made of a stainless steel material and capable of easily joining members for heat insulation and maximizing heat insulation efficiency.

Generally, a window used as a building material can be identified from the inside to the outside of a building, and is widely used for ventilation of a room, and includes a window frame forming an outer frame and a window pane coupled to the window frame.

On the other hand, in a window frame made of a conventional aluminum material, a lot of heat insulating materials have been applied for heat insulation between the outdoor side and the indoor side.

In addition, the conventional window frame provided with the above-described aluminum material can easily form a complicated structure in which the heat insulating material can be joined by extrusion molding aluminum.

Recently, a window frame made of a stainless steel material rather than an aluminum material has been developed, and it is preferable that a heat insulating material coupling structure for heat insulation between the indoor side and the outdoor side is also applied to the window frame made of stainless steel.

However, since such a stainless steel is usually formed by using a roll forming machine or the like, the machining and formability of the stainless steel is much lower than that of aluminum. Therefore, it is required to develop an efficient structure capable of fixing a heat insulating material to a stainless steel window frame .

Therefore, it is required to research and develop a window frame which is made of a stainless steel material, and which can easily combine members for heat insulation and maximize heat insulation efficiency.

Registered Korean Patent No. 0880339 Jan. 16, 2009 Registered. Registration No. 1217213 of Korea Registered on December 24, 2012. Korea Registered Patent No. 1767089 Issue Jul. 08,

In order to solve the above-described problems, the present invention provides an outer frame which is made of a stainless steel material and is formed as a hollow square pipe type having an insertion hole penetrated at the center thereof, and a heat insulating frame assembly And it is an object of the present invention to provide a window frame with an improved heat insulating property which is made of a stainless steel material and can easily join a member for heat insulation and can improve the heat insulation efficiency.

In addition, the technology according to the present invention is easy to manufacture by adopting the heat insulating frame assembly composed of the upper and lower assembling units including the upper and lower heat insulating blocks, the central heat insulating block and the side assembling unit including the side heat insulating block, So that it is possible to maximize the heat insulation efficiency of the heat exchanger.

The present invention for achieving the above-mentioned objects is as follows. That is, the window frame with improved heat insulation according to the present invention is made of stainless steel and has an outer frame formed as a hollow rectangular pipe type having an insertion hole formed at the center thereof and a heat insulating frame assembly Wherein the heat insulating frame assemblies are provided as a pair and are provided in a square bar type so that an assembly groove is formed on both sides and upper and lower heat insulating blocks of a rectangular bar type are fixedly installed to penetrate through the center, And a pair of central insulated blocks formed in a square bar type and disposed in close contact with the center of the upper and lower subassembly units provided as a pair and the upper and lower subassemblies are closely arranged on upper and lower portions of the central heat insulating block And the upper and lower assembly units are opposed to the assembly recesses of the upper and lower assembly units And a side assembly unit including a side body frame in which a pair of assembly projections are formed on upper and lower sides of one side and a side-body heat-insulating block of a rectangular bar type penetrates through the center.

The upper and lower heat insulating blocks, the center heat insulating block, and the side heat insulating block may contain 50 wt% of bottom ash, 10 wt% of fly ash, 5 wt% of glass beads, 15 wt% of clay ash, Preparing 5% by weight of sodium silicate and 5% by weight of an auxiliary additive, preparing a mixed material to obtain a heat insulating material, preparing a reinforcing plate on a zigzag plate, preparing at least one reinforcing plate, Molding the block into a rectangular bar type or a rectangular bar type block by pressing the insulation material to the frame by receiving and pressing the block, and passing the molded block through an oven at a temperature of 80 to 450 DEG C for 25 Min., A calcination process in which the dried block is calcined in a calcining furnace at 900 to 1300 ° C for 35 minutes, and a cooling process in which the calcined block is cooled in nitrogen for 10 minutes. As a heat block, it is preferred that the insulating material applied to the central portion at least in a heat insulating block having at least one reinforcing plate.

The upper and lower heat insulating blocks, the center heat insulating block, and the side heat insulating block are formed by uniformly mixing particles having a bottom ash of 50 wt% or less and 0.3 mm or less and 5 mm or less, 10 to 5 mm 10 wt%, 4.75 to 2.36 mm 40 wt%, 2.36 to 1.18 mm 30 wt%, 1.18 to 0.6 mm 10 wt%, and 0.6 to 0.3 mm 10 wt%.

The reinforcing plate provided at the central portion of the heat insulating material of the upper and lower heat insulating blocks, the central heat insulating block and the side heat insulating block is provided as a zigzag type plate, and is provided with a perforated plate type having a plurality of different through- .

The upper and lower heat insulating blocks, the central heat insulating block, and the side heat insulating block may include third to fifth weight portions of non-slip relative to 100 parts by weight of the heat insulating material in contact with the heat insulating material on both sides of the reinforcing plate during the molding process, It is preferable that the agent is selected from one or a mixture of ceramic powder, aluminum oxide powder, iron oxide powder and non-metal powder, and the particle size is preferably 300 mesh or less.

The upper and lower heat insulating blocks, the central heat insulating block, and the side heat insulating block may include third to fifth weight portions of non-slip relative to 100 parts by weight of the heat insulating material in contact with the heat insulating material on both sides of the reinforcing plate, + &Quot; rod shape, which is selected from ceramic powder, aluminum oxide powder, iron oxide powder, and non-metal powder, or a mixture thereof, It is preferable to apply irregularly to the contacting surface.

The upper and lower heat insulating blocks, the central heat insulating block, and the side heat insulating block are applied to a heat insulating block having the at least one reinforcing plate at the center of the heat insulating material. The upper and lower heat insulating blocks and the central heat insulating block have a reinforcing plate It is preferable that the side heat insulating block is applied as a heat insulating block having two reinforcing plates spaced apart from each other with respect to the center on the center of the heat insulating material.

In addition, a set of the heat insulating frame assemblies, which are shorter than the length of the outer frame, inserted through the insertion holes of the outer frame by interference fit, are provided in four sets so as to form a rectangular frame, The connecting protrusion of the connecting frame is inserted into and connected to the insertion hole of the outer frame to complete the rectangular frame.

According to another aspect of the present invention, there is provided a window frame for manufacturing a window frame of a sliding window, the window frame having an improved heat insulating property, wherein the window frame is made of stainless steel and has a pair of rails spaced from each other, And a heat insulating frame assembly inserted into each of the insertion holes of the outer frame through interference fit, wherein the heat insulating frame assembly is provided as a pair, Upper and lower assembly units each having an assembly groove formed on both sides thereof and having a rectangular bar type upper and lower heat insulating blocks fixedly installed so as to penetrate through the center thereof; , A central insulation block formed in a square bar type and a pair A pair of assembly projections are projected on upper and lower sides of one side of the upper and lower assembly units, which are opposite to the assembly grooves of the upper and lower assembly units, And a side body assembly unit including a side body frame formed by a rectangular bar type side side heat insulating block fixedly installed so as to penetrate through a center thereof.

The upper and lower heat insulating blocks, the center heat insulating block, and the side heat insulating block are formed of 50 wt% of bottom ash, 10 wt% of fly ash, 5 wt% of glass beads, 15 wt% of clay ash, Preparing 5% by weight of sodium silicate and 5% by weight of an auxiliary additive, preparing a mixed material to obtain a heat insulating material, preparing a reinforcing plate on a zigzag plate, preparing at least one reinforcing plate, Molding the block into a rectangular bar type or a rectangular bar type block by pressing the insulation material to the frame by receiving and pressing the block, and passing the molded block through an oven at a temperature of 80 to 450 DEG C for 25 Min., A step of calcining the dried block at a calcination temperature of 900 to 1300 ° C for 35 minutes, and a step of cooling the calcined block by nitrogen for 10 minutes. As a block, it is preferred that the insulating material applied to the central portion at least in a heat insulating block having at least one reinforcing plate.

The upper and lower heat insulating blocks, the center heat insulating block, and the side heat insulating block are formed by uniformly mixing particles having a bottom ash of 50 wt% or less and 0.3 mm or less and 5 mm or less, 10 to 5 mm 10 wt%, 4.75 to 2.36 mm 40 wt%, 2.36 to 1.18 mm 30 wt%, 1.18 to 0.6 mm 10 wt%, and 0.6 to 0.3 mm 10 wt%.

The reinforcing plate provided at the central portion of the heat insulating material of the upper and lower heat insulating blocks, the central heat insulating block and the side heat insulating blocks is provided as a zigzag plate, and is provided as a perforated plate type having a plurality of through holes .

The upper and lower heat insulating blocks, the central heat insulating block, and the side heat insulating block may include third to fifth weight portions of non-slip relative to 100 parts by weight of the heat insulating material in contact with the heat insulating material on both sides of the reinforcing plate during the molding process, It is preferable that the agent is selected from one or a mixture of ceramic powder, aluminum oxide powder, iron oxide powder and non-metal powder, and the particle size is preferably 300 mesh or less.

The upper and lower heat insulating blocks, the central heat insulating block, and the side heat insulating block may include third to fifth weight portions of non-slip relative to 100 parts by weight of the heat insulating material in contact with the heat insulating material on both sides of the reinforcing plate during the molding process, + &Quot; rod shape, which is selected from ceramic powder, aluminum oxide powder, iron oxide powder, and non-metal powder, or a mixture thereof, It is preferable to apply irregularly to the contacting surface.

Further, the upper and lower heat insulating blocks, the center heat insulating block, and the side heat insulating block are applied as a heat insulating block having the at least one reinforcing plate at a central portion of the heat insulating material, and the upper and lower heat insulating blocks and the central heat insulating block have one reinforcing plate It is preferable that the side heat insulating block is applied to a heat insulating block having two reinforcing plates spaced apart from each other by a predetermined distance on both sides with respect to the center in the center of the heat insulating material.

The effect of the window frame with improved heat insulation according to the present invention is as follows.

First, an outer frame formed of a stainless steel material and formed of a hollow square pipe type having an insertion hole penetrated at the center thereof, and a heat insulating frame assembly inserted into the insertion hole of the outer frame through interference, , It is possible to easily combine the members for heat insulation and improve the heat insulation efficiency.

Second, since the heat insulating frame assembly composed of the upper and lower assembling units including the upper and lower heat insulating blocks, the central heat insulating block and the side assembling unit including the side heat insulating blocks is applied, the manufacturing is simple and the heat insulating efficiency for the indoor side and the outdoor side is improved Can be maximized.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a partially separated perspective view showing a window frame with improved heat insulation according to the present invention, in which the outer frame and the heat insulating frame assembly are separated. FIG.
FIG. 2 is a perspective view illustrating a window frame with improved heat insulation according to the present invention. FIG. 2 is a perspective view illustrating a combined frame structure in which an outer frame and an insulating frame assembly are coupled.
3 is a perspective view showing the assembled structure of a heat insulating frame assembly according to the present invention, which is a main part of a window frame with improved heat insulation.
4 is an assembled state sectional view of a heat insulating frame assembly showing an assembling structure for a heat insulating frame assembly which is a main part of a window frame with improved heat insulation according to the present invention.
The present invention relates to a heat insulating frame assembly for a window frame with improved heat insulation, and more particularly, to a heat insulating frame assembly for a window frame with improved heat insulation, which is used for upper and lower heat insulating blocks, side heat insulating blocks and central heat insulating blocks.
FIG. 6 is a view showing a construction using state-separated strainer showing a structure in which four window frames with improved heat insulation according to the present invention are applied and assembled into a rectangular frame type through interconnecting frames. FIG.
FIG. 7 is a construction view showing a state in which the joining state is shown in FIG. 6; FIG.
FIG. 8 is a construction view showing a state in which the joining state of FIG. 6 is taken in a joining state. FIG.
FIG. 9 is a partially separated perspective view showing a window frame with improved heat insulation according to another embodiment of the present invention, in which the outer frame and the heat insulating frame assembly are separated. FIG.
FIG. 10 is a perspective view illustrating a window frame with improved heat insulation according to another embodiment of the present invention. FIG. 10 is a perspective view illustrating a combined frame structure in which an outer frame and an insulating frame assembly are coupled.
FIG. 11 is an assembled state sectional view of a heat insulating frame assembly showing an assembling structure for a heat insulating frame assembly which is a main part of a window frame with improved heat insulation according to another embodiment of the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a window frame with improved heat insulation according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a partially separated perspective view showing a state where the outer frame and the heat insulating frame assembly are separated from each other, FIG. 2 is a view showing a window frame with improved heat insulation according to the present invention , And an outer frame and an insulating frame assembly are coupled to each other.

FIG. 3 is a perspective view showing the assembling structure of the heat insulating frame assembly, which is a main part of the window frame with improved heat insulation according to the present invention, FIG. 4 is a perspective view of the heat insulating frame assembly, Sectional view of an assembled state of the heat insulating frame assembly showing the assembled structure of the heat insulating frame assembly.

FIG. 5 is a schematic view showing a reinforcing plate applied to upper and lower heat insulating blocks, a side heat insulating block and a central heat insulating block, which are essential parts of a heat insulating frame assembly of a window frame with improved heat insulation according to the present invention.

FIG. 6 is a perspective view illustrating a structure in which four window frames with improved heat insulation according to the present invention are applied and assembled into a rectangular frame type through an interconnecting frame, FIG. And FIG. 8 is a cross-sectional view illustrating a jointed state of FIG. 6 in a construction use state.

1 to 8, a window frame with improved heat insulation according to a preferred embodiment of the present invention is formed of a stainless steel material and has an outer frame 100 (see FIG. 1) formed by a hollow rectangular pipe type having an insertion hole 110 formed at the center thereof, And a heat insulating frame assembly 200 inserted into the insertion hole 110 of the outer frame 100 through interference fit.

The heat insulating frame assembly 200 includes upper and lower assembling units 210, a central heat insulating block 220, and a side assembling unit 230.

In detail, the upper and lower assembly units 210 are provided as a pair and are provided in a square bar type so that an assembly groove 212 is formed on both sides, and upper and lower heat insulation blocks 215 of a rectangular bar type are fixedly installed to penetrate the center, And a body frame 211.

In addition, the central heat insulating block 220 is disposed closely to the center of the upper and lower assembly units 210 provided as a pair, and is formed as a square bar type.

The side assembly units 230 are provided in a pair so that the upper and lower assembly units 210 are tightly mounted on both sides of the upper and lower assembly units 210 in close contact with the upper and lower parts of the central heat insulating block 220, A pair of assembly protrusions 232 protruding from upper and lower sides of one side opposite to the assembly groove 212 of the side plate 210 and a rectangular side bar type side heat insulation block 235 extending through the center, And a body frame 231.

The upper and lower heat insulating blocks 215, the central heat insulating blocks 220 and the side heat insulating blocks 235 in the heat insulating frame assembly 200 having the above-described structure are formed by a process of preparing a material, a forming process, 227 and 237 are provided at the center of the heat insulating materials 216, 226, and 236. The heat insulating blocks 216, 226, and 236 may be formed as a heat insulating block having at least one or more reinforcing plates 217,

At this time, the material preparation process was performed in such a manner that 50 wt% of bottom ash, 10 wt% of fly ash, 5 wt% of glass beads, 15 wt% of clay ash, 10 wt% of black ash, 5% by weight of additives are prepared, mixed and mixed to obtain a heat insulating material, and staggered plate-like reinforcing plates 217, 227 and 237 are prepared.

In the molding process, at least one of the reinforcing plates 217, 227, and 237 is disposed at the center of the mold, and then the molding material is received and pressed by the mold to form a square bar type or a rectangular bar type As shown in FIG.

The drying process includes drying the molded block at a temperature of 80 to 450 ° C for 25 minutes while passing the block through the drying furnace.

The firing process includes firing the dried block in a firing furnace at 900 to 1300 ° C for 35 minutes, and cooling the fired block by nitrogen for 10 minutes.

The upper and lower heat insulating blocks 215, the central heat insulating block 220 and the side heat insulating blocks 235 as described above are formed by uniformly mixing granules having a bottom ash of 50 wt% , 4.75 to 5 mm 10 wt%, 4.75 to 2.36 mm 40 wt%, 2.36 to 1.18 mm 30 wt%, 1.18 to 0.6 mm 10 wt%, and 0.6 to 0.3 mm or less based on 100 wt% of bottom ash 10% by weight based on the total weight of the composition.

The upper and lower heat insulating blocks 215, the central heat insulating block 220 and the side heat insulating block 235 are formed on the surfaces of the reinforcing plates 217, 227, and 237, And 3 to 5 parts by weight of non-slip relative to 100 parts by weight.

The non-slip agent may be selected from ceramic powder, aluminum oxide powder, iron oxide powder, and non-metal powder, or a mixture thereof, and preferably has a particle size of 300 mesh or less.

When an appropriate amount of the non-slipping agent is applied to the surfaces of the reinforcing plates 217, 227, and 237 that are on both surfaces of the reinforcing plates 217, 227, and 237, the slip on the contacting surface is suppressed to prevent the reinforcing plates 217, 227, The bonding property can be further enhanced.

The upper and lower heat insulating blocks 215, the central heat insulating block 220 and the side heat insulating block 235 are formed on the surfaces of the reinforcing plates 217, 227, And 3 to 5 parts by weight of non-slipping granules based on 100 parts by weight of the non-slipping granules. The non-slipping granules are selected from one or a mixture of ceramic powders, aluminum oxide powders, iron oxide powders and non- And may be irregularly coated on the surfaces of the reinforcing plates 217, 227, 237 which are in contact with the heat insulating material on both sides of the reinforcing plates 217, 227, 237.

The reinforcing plates 217, 227 and 237 provided at the central portions of the heat insulating materials 216, 226 and 236 of the upper and lower heat insulating blocks 215, the central heat insulating block 220 and the side heat insulating blocks 235, As shown in the figure, it is preferable to provide a zigzag type plate and a perforated plate type in which a plurality of through holes 217a, 227a, and 237a having a predetermined spacing and a different size are formed.

The upper and lower heat insulating block 215, the center heat insulating block 220 and the side heat insulating block 235 are provided with the at least one reinforcing plate 217, 227, 237 at the center of the heat insulating materials 216, 226, 236 The upper and lower heat insulating blocks 215 and the central heat insulating block 220 are formed of a heat insulating block having one reinforcing plate 217, 227 and 237 at the center of the heat insulating materials 216, 226 and 236 It is desirable to apply it.

The side heat insulating block 235 may be applied to a heat insulating block having two reinforcing plates 217, 227 and 237 spaced apart from each other by a predetermined distance from the center of the heat insulating materials 216, 226 and 236 More preferable.

6 to 8, the heat insulating frame assembly 200, which is shorter than the length of the outer frame 100, is installed in the outer frame (not shown) 100 is inserted into the insertion hole 110 through interference fit, is provided as four sets, and is installed and installed so as to form a rectangular frame.

At this time, the corner portions of the four sets of facing rectangular frames are connected by inserting the connection protrusion 310 of the connection frame 300 into the insertion hole 110 of the outer frame 100 to complete the rectangular frame desirable.

According to the window frame with improved heat insulation according to the present invention having the above-described structure, the outer frame and the outer frame are formed of a hollow square pipe type, which is made of stainless steel and has an insertion hole formed at the center thereof. The heat insulating frame assembly includes the heat insulating frame assembly. The heat insulating member can be easily joined to the heat insulating member, and the heat insulating efficiency can be improved.

Furthermore, since the heat insulating frame assembly composed of the upper and lower assembling units including the upper and lower heat insulating blocks, the central heat insulating block and the side assembling unit including the side heat insulating blocks is applied, the manufacturing is simple and the heat insulating efficiency for the indoor side and the outdoor side is improved It can be maximized.

FIG. 9 is a partially separated perspective view showing a state where the outer frame and the heat insulating frame assembly are separated from each other according to another embodiment of the present invention, and FIG. 10 is a perspective view of a window frame according to another embodiment of the present invention FIG. 5 is a perspective view showing a window frame with improved heat insulation, showing a state in which the outer frame and the heat insulating frame assembly are coupled.

9 to 11 differ only in the outline frame from the embodiment described with reference to Figs. 1 to 8. Therefore, the detailed structure of the heat insulating frame assembly will be described with reference to Figs. 1 to 8 And the detailed description of the components having the same reference numerals will be omitted.

The window frame with improved thermal insulation according to another embodiment of the present invention is a window frame for manufacturing a window frame of a sliding window, and is provided with a stainless steel material. The window frame is spaced apart from both sides of the upper center, And an outer frame 100 having a plurality of insertion holes 110 formed in the width direction of the rail 101 and an insertion hole 110 of the outer frame 100 through interference fit And an insulation frame assembly (200).

The heat insulating frame assembly 200 includes upper and lower assembling units 210, a central heat insulating block 220, and a side assembling unit 230.

In detail, the upper and lower assembly units 210 are provided as a pair and are provided in a square bar type so that an assembly groove 212 is formed on both sides, and upper and lower heat insulation blocks 215 of a rectangular bar type are fixedly installed to penetrate the center, And a body frame 211.

In addition, the central heat insulating block 220 is disposed closely to the center of the upper and lower assembly units 210 provided as a pair, and is formed as a square bar type.

The side assembly units 230 are provided in a pair so that the upper and lower assembly units 210 are tightly mounted on both sides of the upper and lower assembly units 210 in close contact with the upper and lower parts of the central heat insulating block 220, A pair of assembly protrusions 232 protruding from upper and lower sides of one side opposite to the assembly groove 212 of the side plate 210 and a rectangular side bar type side heat insulation block 235 extending through the center, And a body frame 231.

The upper and lower heat insulating blocks 215, the central heat insulating blocks 220 and the side heat insulating blocks 235 in the heat insulating frame assembly 200 having the above-described structure are formed by a process of preparing a material, a forming process, 227 and 237 are provided at the center of the heat insulating materials 216, 226, and 236. The heat insulating blocks 216, 226, and 236 may be formed as a heat insulating block having at least one or more reinforcing plates 217,

At this time, the material preparation process was performed in such a manner that 50 wt% of bottom ash, 10 wt% of fly ash, 5 wt% of glass beads, 15 wt% of clay ash, 10 wt% of black ash, 5% by weight of additives are prepared, mixed and mixed to obtain a heat insulating material, and staggered plate-like reinforcing plates 217, 227 and 237 are prepared.

In the molding process, at least one of the reinforcing plates 217, 227, and 237 is disposed at the center of the mold, and then the molding material is received and pressed by the mold to form a square bar type or a rectangular bar type As shown in FIG.

The drying process includes drying the molded block at a temperature of 80 to 450 ° C for 25 minutes while passing the block through the drying furnace.

The firing process includes firing the dried block in a firing furnace at 900 to 1300 ° C for 35 minutes, and cooling the fired block by nitrogen for 10 minutes.

The upper and lower heat insulating blocks 215, the central heat insulating block 220 and the side heat insulating blocks 235 as described above are formed by uniformly mixing granules having a bottom ash of 50 wt% , 4.75 to 5 mm 10 wt%, 4.75 to 2.36 mm 40 wt%, 2.36 to 1.18 mm 30 wt%, 1.18 to 0.6 mm 10 wt%, and 0.6 to 0.3 mm or less based on 100 wt% of bottom ash 10% by weight based on the total weight of the composition.

The bottom ash applied in the material preparation process is a relatively lightweight material such as coal ash that is used as a fuel in a thermal power plant and has a porous property. The bottom ash can be lightened when it is applied to a window frame of the present invention .

The upper and lower heat insulating blocks 215, the central heat insulating block 220 and the side heat insulating block 235 are formed on the surfaces of the reinforcing plates 217, 227, and 237, And 3 to 5 parts by weight of non-slip relative to 100 parts by weight.

The non-slip agent may be selected from ceramic powder, aluminum oxide powder, iron oxide powder, and non-metal powder, or a mixture thereof, and preferably has a particle size of 300 mesh or less.

When an appropriate amount of the non-slipping agent is applied to the surfaces of the reinforcing plates 217, 227, and 237 that are on both surfaces of the reinforcing plates 217, 227, and 237, the slip on the contacting surface is suppressed to prevent the reinforcing plates 217, 227, The bonding property can be further enhanced.

The upper and lower heat insulating blocks 215, the central heat insulating block 220 and the side heat insulating block 235 are formed on the surfaces of the reinforcing plates 217, 227, And 3 to 5 parts by weight of non-slipping granules based on 100 parts by weight of the non-slipping granules. The non-slipping granules are selected from one or a mixture of ceramic powders, aluminum oxide powders, iron oxide powders and non- And may be irregularly coated on the surfaces of the reinforcing plates 217, 227, 237 which are in contact with the heat insulating material on both sides of the reinforcing plates 217, 227, 237.

The reinforcing plates 217, 227 and 237 provided at the central portions of the heat insulating materials 216, 226 and 236 of the upper and lower heat insulating blocks 215, the central heat insulating block 220 and the side heat insulating blocks 235, As shown in the figure, it is preferable to provide a zigzag type plate and a perforated plate type in which a plurality of through holes 217a, 227a, and 237a having a predetermined spacing and a different size are formed.

The upper and lower heat insulating block 215, the center heat insulating block 220 and the side heat insulating block 235 are provided with the at least one reinforcing plate 217, 227, 237 at the center of the heat insulating materials 216, 226, 236 The upper and lower heat insulating blocks 215 and the central heat insulating block 220 are formed of a heat insulating block having one reinforcing plate 217, 227 and 237 at the center of the heat insulating materials 216, 226 and 236 It is desirable to apply it.

The side heat insulating block 235 may be applied to a heat insulating block having two reinforcing plates 217, 227 and 237 spaced apart from each other by a predetermined distance from the center of the heat insulating materials 216, 226 and 236 More preferable.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, the invention is not limited thereto. Various modifications may be made by those skilled in the art. Are included in the scope of the present invention.

100: outer frame 101: rail
110: insertion hole 200: insulation frame assembly
210: upper and lower assembly unit 211: upper and lower body frame
212: Assembly groove 215: Upper and lower insulation block
216: Insulating material 217: Reinforced plate
217a: Through hole 220: Central insulation block
226: Insulation material 227: Reinforced plate
227a: through hole 230: side assembly unit
231: side body frame 232: assembling projection
235: Side Insulation Block 236: Insulation
237: reinforcing plate 237a: through hole
300: connection frame 310: connection projection

Claims (15)

And an outer frame (100) formed of a hollow square pipe type having an insertion hole (110) formed at the center thereof through a stainless steel material and a heat insulating frame Assembly 200,
The heat insulating frame assemblies 200 are provided as a pair and are provided in a square bar type so that an assembly groove 212 is formed on both sides and upper and lower heat insulating blocks 215 of a rectangular bar type are fixedly installed to penetrate the center, An upper and a lower assembling unit 210 constituted of a lower case 211,
A central heat insulation block 220 disposed in close contact with the center of the upper and lower assembly units 210 and provided in a pair,
The upper and lower assembly units 210 are closely contacted and assembled on both sides of the upper and lower assembly units 210 in close contact with the upper and lower parts of the central heat insulating block 220, Side side heat insulating block 235 protruding from each other and having a pair of assembly protrusions 232 protruding from upper and lower sides of the opposite side and having a side body frame 231 fixedly installed at the center so as to penetrate through the center, And a unit (230). The method according to claim 1,
The upper and lower heat insulating block 215, the center heat insulating block 220 and the side heat insulating block 235 are made of a mixture of 50 wt% of bottom ash, 10 wt% of fly ash, 5 wt% of glass beads, 15 wt% of clay ash, 10% by weight for blackening, 5% by weight of sodium silicate and 5% by weight of an auxiliary additive are prepared, mixed and mixed to obtain a heat insulating material, and a preparing process for preparing reinforcing plates 217, 227 and 237 on a zigzag plate ,
At least one reinforcing plate (217, 227, 237) among the prepared materials is arranged in the central portion of the mold, and the heat insulating material is accommodated in the mold and pressed by a press to form a rectangular bar type or a rectangular bar type block Molding process,
Drying the molded block at a temperature of 80 to 450 DEG C for 25 minutes while passing through the drying furnace,
A firing process in which the dried block is fired in a firing furnace at 900 to 1300 DEG C for 35 minutes and
A heat insulating block obtained by performing a cooling process of cooling the fired block by nitrogen for 10 minutes and a heat insulating block having at least one reinforcing plate 217, 227, 237 at the center of the heat insulating materials 216, 226, 236 Wherein the window frame has an improved heat insulation property. 3. The method of claim 2,
The upper and lower heat insulating block 215, the central heat insulating block 220 and the side heat insulating block 235 are formed by mixing the 50 wt%
4.75 to 5 mm 10 wt%, 4.75 to 2.36 mm 40 wt%, 2.36 to 1.18 mm 30 wt%, 1.18 to 0.6 mm 10 wt%, and 0.6 to 0.3 mm or less 10 wt% % Of the total weight of the window frame. 3. The method of claim 2,
The reinforcing plates 217, 227 and 237 provided at the central portions of the heat insulating materials 216, 226 and 236 of the upper and lower heat insulating blocks 215, the central heat insulating blocks 220 and the side heat insulating blocks 235 are formed in a zigzag shape , And is provided as a perforated plate type in which a plurality of through holes (217a, 227a, 237a) having different sizes are formed at regular intervals. 3. The method of claim 2,
The upper and lower heat insulating blocks 215, the central heat insulating block 220, and the side heat insulating blocks 235,
3 to 5 parts by weight of non-slip relative to 100 parts by weight of the heat insulating material are included in the surfaces of the reinforcing plates 217, 227 and 237,
Characterized in that the non-slip agent is selected from one or a mixture of ceramic powder, aluminum oxide powder, iron oxide powder, and non-metal powder, and the particle size is 300 mesh or less. 3. The method of claim 2,
The upper and lower heat insulating block 215, the central heat insulating block 220 and the side heat insulating block 235 are formed by inserting 100 weight of the heat insulating material 100 on the surfaces of the reinforcing plates 217, 227, And 3 to 5 parts by weight of a volatile non-slipping agent, wherein the non-slipping agent is selected from the group consisting of ceramic powder, aluminum oxide powder, iron oxide powder and non-metal powder,
Wherein the reinforcing plates (217, 227, 237) are formed in a '+' shape having different sizes from each other and are irregularly coated on the surfaces of the reinforcing plates (217, 227, 237) contacting the heat insulating material. 3. The method of claim 2,
The upper and lower heat insulating blocks 215, the center heat insulating block 220 and the side heat insulating block 235 are formed by inserting heat insulating materials 216, 226, 236 at the center thereof with the at least one reinforcing plates 217, 227, As a block,
The upper and lower heat insulating blocks 215 and the central heat insulating block 220 are applied as a heat insulating block having one reinforcing plate 217, 227 and 237 at the center of the heat insulating materials 216, 226 and 236,
The side heat insulation block 235 is applied to a heat insulation block having two reinforcing plates 217, 227 and 237 spaced apart from each other by a predetermined distance from the center of the heat insulating materials 216, 226 and 236 Window frame with improved insulation. The method according to claim 1,
One set in which the heat insulating frame assembly 200 provided with a length shorter than the length of the outer frame 100 is inserted into the insertion hole 110 of the outer frame 100 through interference fit is provided in four sets, It is installed and constructed so as to form a frame,
The corner portions of the four sets of facing rectangular frames are formed by connecting the connection protrusions 310 of the connection frame 300 to the insertion holes 110 of the outer frame 100 to complete a rectangular frame Window frame with improved insulation. A window frame for manufacturing a window frame of a sliding window,
A pair of rails 101 protruding from the center of the upper part and being spaced apart from each other on both sides of the rails 101 and having a plurality of insertion holes 110 formed in the width direction below the rails 101, And a heat insulating frame assembly (200) inserted into each of the insertion holes (110) of the outer frame (100) through interference fit,
The heat insulating frame assemblies 200 are provided as a pair and are provided in a square bar type so that an assembly groove 212 is formed on both sides and upper and lower heat insulating blocks 215 of a rectangular bar type are fixedly installed to penetrate the center, An upper and a lower assembling unit 210 constituted of a lower case 211,
A central heat insulation block 220 disposed in close contact with the center of the upper and lower assembly units 210 and provided in a pair,
The upper and lower assembly units 210 are closely contacted and assembled on both sides of the upper and lower assembly units 210 in close contact with the upper and lower parts of the central heat insulating block 220, Side side heat insulating block 235 protruding from each other and having a pair of assembly protrusions 232 protruding from upper and lower sides of the opposite side and having a side body frame 231 fixedly installed at the center so as to penetrate through the center, And a unit (230). 10. The method of claim 9,
The upper and lower heat insulating block 215, the center heat insulating block 220 and the side heat insulating block 235 are made of a mixture of 50 wt% of bottom ash, 10 wt% of fly ash, 5 wt% of glass beads, 15 wt% of clay ash, 10% by weight for blackening, 5% by weight of sodium silicate and 5% by weight of an auxiliary additive are prepared, mixed and mixed to obtain a heat insulating material, and a preparing process for preparing reinforcing plates 217, 227 and 237 on a zigzag plate ,
At least one reinforcing plate (217, 227, 237) among the prepared materials is arranged in the central portion of the mold, and the heat insulating material is accommodated in the mold and pressed by a press to form a rectangular bar type or a rectangular bar type block Molding process,
Drying the molded block at a temperature of 80 to 450 DEG C for 25 minutes while passing through the drying furnace,
A firing process in which the dried block is fired in a firing furnace at 900 to 1300 DEG C for 35 minutes and
A heat insulating block obtained by performing a cooling process of cooling the fired block by nitrogen for 10 minutes and a heat insulating block having at least one reinforcing plate 217, 227, 237 at the center of the heat insulating materials 216, 226, 236 Wherein the window frame has an improved heat insulation property. 11. The method of claim 10,
The upper and lower heat insulating block 215, the central heat insulating block 220 and the side heat insulating block 235 are formed by mixing the 50 wt%
4.75 to 5 mm 10 wt%, 4.75 to 2.36 mm 40 wt%, 2.36 to 1.18 mm 30 wt%, 1.18 to 0.6 mm 10 wt%, and 0.6 to 0.3 mm or less 10 wt% % Of the total weight of the window frame. 11. The method of claim 10,
The reinforcing plates 217, 227 and 237 provided at the central portions of the heat insulating materials 216, 226 and 236 of the upper and lower heat insulating block 215, the central heat insulating block 220 and the side heat insulating block 235 are formed as a zigzag plate , And is provided as a perforated plate type in which a plurality of through holes (217a, 227a, 237a) having different sizes are formed at regular intervals. 11. The method of claim 10,
The upper and lower heat insulating blocks 215, the central heat insulating block 220, and the side heat insulating blocks 235,
3 to 5 parts by weight of non-slip relative to 100 parts by weight of the heat insulating material are included in the surfaces of the reinforcing plates 217, 227 and 237,
Characterized in that the non-slip agent is selected from one or a mixture of ceramic powder, aluminum oxide powder, iron oxide powder, and non-metal powder, and the particle size is 300 mesh or less. 11. The method of claim 10,
The upper and lower heat insulating block 215, the central heat insulating block 220 and the side heat insulating block 235 are formed by inserting 100 weight of the heat insulating material 100 on the surfaces of the reinforcing plates 217, 227, And 3 to 5 parts by weight of a volatile non-slipping agent, wherein the non-slipping agent is selected from the group consisting of ceramic powder, aluminum oxide powder, iron oxide powder and non-metal powder,
Wherein the reinforcing plates (217, 227, 237) are formed in a '+' shape having different sizes from each other and are irregularly coated on the surfaces of the reinforcing plates (217, 227, 237) contacting the heat insulating material. 11. The method of claim 10,
The upper and lower heat insulating blocks 215, the center heat insulating block 220 and the side heat insulating block 235 are formed by inserting heat insulating materials 216, 226, 236 at the center thereof with the at least one reinforcing plates 217, 227, As a block,
The upper and lower heat insulating blocks 215 and the central heat insulating block 220 are applied as a heat insulating block having one reinforcing plate 217, 227 and 237 at the center of the heat insulating materials 216, 226 and 236,
The side heat insulation block 235 is applied to a heat insulation block having two reinforcing plates 217, 227 and 237 spaced apart from each other by a predetermined distance from the center of the heat insulating materials 216, 226 and 236 Window frame with improved insulation.

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