CN111757967B - Thermal insulation door and window frame - Google Patents

Abstract

The present invention relates to a heat insulation door and window frame, wherein a heat insulation block contacts and supports a glass window, the heat conductivity transmitted from an outdoor side frame and an indoor side frame to the glass window is reduced, and heat insulation frames for supporting the outdoor side frame and the indoor side frame are arranged at intervals to improve the heat insulation performance. The present invention provides an insulated door and window frame for supporting a glass window for partitioning the interior and exterior of a building, comprising: an indoor side frame supporting a glass window inside a building; an outdoor-side frame supporting a glass window at the outside of a building; a heat insulation frame disposed between the indoor and outdoor side frames and supporting the glass window; and a heat insulation block provided at a side of the heat insulation frame, supporting the glass window, forming a heat insulation frame clamping groove for combining with the heat insulation frame at an upper end of the indoor side frame along a length direction of the indoor side frame, forming a heat insulation frame combining protrusion for combining with the heat insulation frame clamping groove at a lower end of the heat insulation frame, an end of the heat insulation frame combining protrusion being bent to one direction so as to be combined to the heat insulation frame clamping groove only in one direction, the heat insulation frame being composed of a plurality of blocks and being provided spaced apart from each other along the length direction of the indoor side frame.

Description

Thermal insulation door and window frame

Technical Field

The present invention relates to a heat-insulated door and window frame, and more particularly, to a heat-insulated door and window frame in which a heat-insulating block contacts and supports a glass window to reduce heat conductivity transferred from an outdoor side frame and an indoor side frame to the glass window, and heat-insulated frames for supporting the outdoor side frame and the indoor side frame are provided at regular intervals to improve heat-insulating performance.

Background

The door and window generally refers to various windows or doors provided in an opening such as a window or a doorway to partition the interior and exterior of a building.

Generally, a door or window having only one glass is poor in heat insulation and sound insulation, and therefore, a double-glazing is mostly used for doors or windows constructed in halls, schools, hospitals, or businesses, which have certain requirements for heat insulation and sound insulation.

In the case of constructing a door, a window, an indoor partition, or the like, a frame for a door or window to which the double glazing is fixedly attached is generally formed as a quadrangular frame, and the double glazing or a door for entrance and exit is attached to an inner area of the quadrangle.

However, in the conventional door and window frame, both sides of the double glass are in contact with the indoor side frame and the outdoor side frame, respectively, and the door and window frame is formed of an integrated metal plate material and easily conducts heat, so that a dew condensation phenomenon occurs due to a temperature difference between indoor and outdoor, and heat dissipated to the outside is excessive, thereby causing a problem of a low heat insulation property.

Disclosure of Invention

Technical problem to be solved

The invention provides an insulated door and window frame, wherein a heat insulation block contacts and supports a glass window to reduce the heat conductivity transmitted from an outdoor side frame and an indoor side frame to the glass window, and heat insulation frames for supporting the outdoor side frame and the indoor side frame are arranged at intervals according to a specified distance to improve the heat insulation performance.

(II) technical scheme

In order to solve the technical problem, the present invention provides an insulated door and window frame for supporting a glass window partitioning the interior and exterior of a building, comprising: an indoor side frame supporting the glass window inside a building; an outdoor-side frame supporting the glass window at the outside of the building; an insulation frame disposed between the indoor and outdoor side frames, supporting the glass window; and a heat insulation block disposed at a side of the heat insulation frame, supporting the glass window, wherein a heat insulation frame clamping groove for combining with the heat insulation frame is formed at an upper end of the indoor side frame along a length direction of the indoor side frame, a heat insulation frame combining protrusion for combining with the heat insulation frame clamping groove is formed at a lower end of the heat insulation frame, an end of the heat insulation frame combining protrusion is bent to one direction so as to be combined to the heat insulation frame clamping groove only in one direction, the heat insulation frame is composed of a plurality of blocks, and is disposed to be spaced apart from each other along the length direction of the indoor side frame.

According to the thermal break door and window frame of the present invention, a first protrusion extending from both side surfaces of an upper end of the indoor-side frame may be protrusively formed in the indoor-side frame, the heat insulation block may be disposed between the first protrusion and the heat insulation frame, and a height of the heat insulation block may be higher than a height of the first protrusion.

According to the thermal window and door frame of the present invention, a first thermal insulation frame connection part for connection with the thermal insulation frame may be formed at a lower end of the outdoor side frame along a length direction of the outdoor side frame.

According to the thermal break door and window frame of the present invention, the thermal break frame may comprise: an indoor side frame fastening structure body, the lower end of which forms the heat insulation frame combination protrusion, and the opposite surface of the heat insulation frame combination protrusion forms a fastening part combination groove; and an outdoor side frame fastening structure, the lower end of which forms a fastening part combining protrusion for combining with the fastening part combining groove, the upper end of which forms a second heat insulation frame connecting part for connecting with the first heat insulation frame connecting part, and the outdoor side frame fastening structure wraps at least a part of the outer side surface of the indoor side frame fastening structure.

According to the thermal break door and window frame of the present invention, the indoor side frame may comprise: a frame body portion; and the adapter part is used for combining the frame body part and the heat insulation frame, and the heat insulation frame clamping groove and the first protruding part are formed at the upper end of the adapter part.

According to the thermal break door and window frame of the present invention, a third protrusion extending from both side surfaces of a lower end of the indoor side frame may be protrudingly formed in the indoor side frame, and may further include: a first structural reinforcement inserted into the inside of the third protrusion to be combined with the indoor side frame; and a second structural reinforcement inserted into the inside of the indoor side frame to be combined with the indoor side frame and perpendicular to the first structural reinforcement.

According to the heat insulation door and window frame of the present invention, the first fastening groove may be formed at both side surfaces of the lower end portion of the indoor side frame, and the heat insulation door and window frame may further include an illumination portion including illumination therein, and a first fastening protrusion for being coupled with the first fastening groove may be formed at an upper end thereof.

The insulated door and window frame according to the present invention may further comprise: an exterior material provided along outer side surfaces of the indoor-side frame and the outdoor-side frame; and an adhesive agent disposed between the indoor-side frame and the exterior material or between the outdoor-side frame and the exterior material, and adhering the indoor-side frame and the exterior material or the outdoor-side frame and the exterior material.

(III) advantageous effects

The thermal break door and window frame according to the present invention has the following effects.

First, the glass window is not in direct contact with the frame, and the glass window is supported by the heat insulating block to connect the glass window and the frame through the heat insulating block, thereby reducing thermal conductivity transferred from the outside.

Second, heat insulation frames for supporting the outdoor side frame and the indoor side frame are provided at a predetermined interval, and an air gap is formed between the outdoor side frame and the indoor side frame, thereby improving heat insulation performance.

Thirdly, the heat insulation frame comprises an adapter part, so that prefabricated frame components such as forming rods, square tubes and combination rods which are widely used on the site in the past can be combined with the heat insulation frame, and the application example can be expanded.

Fourth, a structural reinforcement such as carbon fiber is incorporated into the frame, so that the tensile strength performance of the frame can be improved.

Fifth, an exterior material is coupled to the outside of the frame, thereby preventing corrosion of the frame and improving aesthetic quality.

Sixth, the exterior material combined to the outside of the frame includes lighting, thereby enabling to create an environment and to improve aesthetic.

Drawings

Fig. 1 is a perspective view showing a first embodiment of a thermal break door and window frame according to the present invention.

Fig. 2 is a sectional view showing the thermal break door and window frame of fig. 1.

Figure 3 is a diagram showing in particular the thermal insulating frame of the thermal break door and window frame of figure 1.

Fig. 4 is a view specifically showing an outdoor side frame of the thermal break door and window frame of fig. 1.

Fig. 5 is a view specifically showing an indoor side frame of the thermal break door window frame of fig. 1.

Fig. 6 is a view showing an arrangement structure of an indoor side frame and a heat insulation frame of the heat insulated door and window frame of fig. 1.

Fig. 7 is a view showing an arrangement structure of an indoor side frame, a heat insulation frame, and a heat insulation block of the thermal break door window frame of fig. 1.

Fig. 8 is a view showing a second embodiment of a thermal break door and window frame according to the present invention.

FIG. 9 is a view showing a third embodiment of a thermal break door and window frame according to the present invention.

FIG. 10 is a view showing a fourth embodiment of a thermal break door and window frame according to the present invention.

Fig. 11 is a view specifically showing an illuminating portion of the thermal break door and window frame of fig. 10.

Detailed Description

Hereinafter, preferred embodiments of the present invention that can specifically solve the above-described technical problems to be solved will be described in detail with reference to the accompanying drawings. In describing the present embodiment, the same names and the same reference numerals are used for the same constituents, and additional description thereof will be omitted below.

Next, a first embodiment of a thermal break door and window frame according to the present invention will be described with reference to fig. 1 to 7.

As shown in fig. 1 to 7, the heat-insulated door and window frame according to the present embodiment includes an indoor side frame 1100, an outdoor side frame 1200, a heat-insulated frame 1300, a heat-insulated block 1500, a first coupling member B1, a cushion 1610, a second silicone coupling portion 1620, an exterior material C, and an adhesive a.

As shown in fig. 1, 2, and 4, the indoor-side frame 1100 is formed by forming heat-insulating frame notches in the upper-end center portion along the longitudinal direction with reference to the frame body, and by protruding first protruding portions 1103 extending from both upper-end side surfaces.

At this time, the heat insulation frame slots include a first heat insulation frame slot 1101 and a second heat insulation frame slot 1102, and the first heat insulation frame slot 1101 and the second heat insulation frame slot 1102 are slots formed in opposite directions with respect to the center of the frame body, which will be described in detail later.

As shown in fig. 1, 2 and 3, a first heat insulation frame connection portion 1211 is formed at a lower center portion of the outdoor side frame 1200, and specifically, the outdoor side frame 1200 includes a first outdoor side frame 1210 and a second outdoor side frame 1220.

As described above, the first outdoor-side frame 1210 has the first heat insulation frame connection 1211 formed at the center of the lower end thereof, and both ends of the first outdoor-side frame 1210 extend in the upper direction to protrude to form the first outdoor-side frame coupling portion 1212, and the first outdoor-side frame coupling portion 1212 has the concave-convex portion formed therein.

The second outdoor-side frame 1220 has a shape of "Contraband", has second outdoor-side frame coupling parts 1221 formed at both ends thereof, the second outdoor-side frame coupling parts 1221 being formed in a shape corresponding to a concave-convex part formed in the first outdoor-side frame coupling part 1212, and couples the first outdoor-side frame 1210 and the second outdoor-side frame 1220 by coupling the first outdoor-side frame coupling part 1212 and the second outdoor-side frame coupling part 1221.

The indoor side frame 1100 and the outdoor side frame 1200 may be formed of a metal material such as aluminum, stainless steel (SUS), or the like, or a material having the same strength, and specifically, the indoor side frame 1100 and the outdoor side frame 1200 may be formed in a structural shape by extrusion and molding according to the material.

As shown in fig. 2, the exterior material C is disposed along the outer surfaces of the indoor side frame 1100 and the outdoor side frame 1200 to prevent corrosion of the frames and improve aesthetic quality, and may be composed of iron, aluminum, SUS, PVC, an aluminum composite plate, or the like.

The adhesive a is disposed between the indoor side frame 1100 and the exterior material C and between the outdoor side frame 1200 and the exterior material C to bond the indoor side frame 1100 and the outdoor side frame 1200 to the exterior material C, and may be inserted into a bonding groove formed on an inner surface of the indoor side frame 1100 or an outer surface of the outdoor side frame 1200 to bond the indoor side frame 1100 and the outdoor side frame 1200 to the exterior material C.

As shown in fig. 1, 2, and 5 to 7, the heat insulation frame 1300 is disposed between the indoor side frame 1100 and the outdoor side frame 1200, and the lower end and the upper end of the heat insulation frame 1300 are connected to the heat insulation frame clamping groove and the first heat insulation frame connection portion 1211, respectively, to connect the indoor side frame 1100 and the outdoor side frame 1200.

Specifically, the heat insulating frame 1300 includes an indoor side frame fastening structure 1310, an ethylene-propylene (azo) 1330, and an outdoor side frame fastening structure 1320.

An insulating frame coupling protrusion 1311 for coupling to the insulating frame locking groove is formed at a lower end of the indoor side frame fastening structure 1310, and a fastening portion coupling groove 1312 is formed at the other surface opposite to the one surface on which the insulating frame coupling protrusion 1311 is formed.

An end of the insulation frame coupling protrusion 1311 is bent to one direction to be coupled to the insulation frame catching groove only in one direction so as to be inserted into only one of the first and second insulation frame catching grooves 1101 and 1102.

That is, the insulation frame coupling protrusion 1311 is formed of a single protrusion, and thus the insulation frame coupling protrusion 1311 may be selectively inserted into the first insulation frame catching groove 1101 or the second insulation frame catching groove 1102, thereby being more easily coupled.

The sub-release portion 1330 is formed of a polyurethane material and disposed inside the indoor side frame fastening structure 1310, and the sub-release portion 1330 is included in the heat insulation frame 1300 to improve heat insulation performance by blocking heat transfer of hot and cold air in the outside and the inside of the room.

At this time, the material of the sub-release portion 1330 may be composed of polyamide or polyurethane, and the material of the sub-release portion 1330 may be replaced with a material having heat insulation performance and good mechanical properties according to temperature, in addition to the material.

That is, by composing the sub-release portion 1330 and the outdoor-side-frame fastening structure 1320 to be described later at the same time, the heat insulation effect can be maximized.

The outdoor-side-frame fastening structure 1320 has fastening-portion coupling protrusions 1321 formed at the lower end, i.e., both ends, to be coupled to the fastening-portion coupling grooves 1312, and a second insulation-frame coupling portion 1322 formed at the upper end to be coupled to the first insulation-frame coupling portion 1211.

The indoor-side frame fastening structure 1310 is inserted into the outdoor-side frame fastening structure 1320, and the fastening-portion coupling groove 1312 is coupled to the fastening-portion coupling protrusion 1321, so that the outdoor-side frame fastening structure 1320 wraps at least a portion of the outer surface of the indoor-side frame fastening structure 1310.

The outdoor-side frame fastening structure 1320 may be made of polyamide, and the material of the outdoor-side frame fastening structure 1320 may be replaced with a material having heat insulating properties and good mechanical properties according to temperature, in addition to the material.

As shown in fig. 6 and 7, the heat insulation frame 1300 includes a first heat insulation frame 1300a, a second heat insulation frame 1300b spaced apart from the first heat insulation frame 1300a, and a third heat insulation frame 1300c spaced apart from the second heat insulation frame 1300 b.

The heat insulation frame 1300 is not integrated, and is spaced apart from the heat insulation blocks 1500 by a predetermined distance as described above, so that it is possible to reduce the amount of hot air or cold air transferred and moved from the indoor side frame 1100 or the outdoor side frame 1200 through the heat insulation frame 1300.

Also, the heat insulation frames 1300 are spaced apart from each other, and an air gap is formed between the first heat insulation frame 1300a and the third heat insulation frame 1300c, and the air gap can improve heat transfer of hot air and cold air blocked from the outside and the inside, thereby improving heat insulation performance.

The window glass 1400 is positioned between the indoor side frame 1100 and the outdoor side frame 1200, and an end portion of the window glass 1400, that is, the first silicone coupling portion 1440 or the window glass fixing portion 2460 included in the window glass 1400 is disposed to face a side surface of the heat insulating frame 1300, and a specific configuration of the window glass 1400 and fixing of the window glass 1400 will be described later.

At least a portion of the thermal insulating block 1500 is disposed between the first protrusions 1103 to support the glass window 1400. That is, the lower end of the heat insulating block 1500 contacts the upper end of the indoor side frame 1100, and the upper end of the heat insulating block 1500 contacts the glass window 1400. At this time, the height of the heat insulation block 1500 is higher than that of the first protrusion 1103.

The material of the heat insulating block 1500 is a foamed plate-shaped heat insulating material, and the material of the heat insulating block 1500 may be replaced with a material having heat insulating properties and good mechanical properties according to temperature and stress.

Further, although not shown in the drawings, the heat insulating block 1500 may have a multi-layer structure to further improve the heat insulating effect, and each of the heat insulating blocks having the multi-layer structure may be made of different materials.

The first coupling member B1 penetrates the first outdoor side frame 1210, the heat insulation frame 1300, and the indoor side frame 1100 in this order, and finally couples the outdoor side frame 1200, the heat insulation frame 1300, and the indoor side frame 1100.

As shown in fig. 2, the first coupling member B1 may be formed of a screw, and threads to be screw-coupled with the first coupling member B1 may be formed in the first outdoor-side frame 1210, the heat insulation frame 1300, and the indoor-side frame 1100, into which the first coupling member B1 is inserted.

Of course, when the first outdoor side frame 1210, the heat insulation frame 1300, and the indoor side frame 1100 included in the heat insulated window and door frame according to the present invention are structurally fixed by insertion-coupling or by an adhesive, the first coupling member B1 may be omitted.

The buffer material 1610 is disposed between the first outdoor-side frame 1210 and the glass window 1400 to perform a buffer function, and simultaneously, the glass window 1400 is maintained in a structurally firm state and is prevented from being broken by an external force.

The second silicone coupling part 1620 is disposed between the first outdoor side frame 1210 and the glass window 1400, and is located at an outer region of the buffer material 1610 with the first outdoor side frame 1210 as a center, and couples the first outdoor side frame 1210 and the glass window 1400 to prevent external air from entering between the first outdoor side frame 1210 and the glass window 1400.

As described above, the outdoor side frame 1200, the heat insulation frame 1300, and the indoor side frame 1100 of the heat insulated window and door frame according to the present embodiment are coupled by the first coupling member B1, and the glass window 1400 provided between the outdoor side frame 1200 and the indoor side frame 1100 is fixed by the heat insulation block 1500, the buffer 1610, and the second silicone coupling portion 1620.

At this time, the height of the heat insulation block 1500 is higher than that of the first protrusion 1103, the glass window 1400 is in contact with the heat insulation block 1500 without contacting the indoor side frame 1100, and the heat insulation block 1500 supports the glass window 1400, thereby minimizing a heat transfer phenomenon occurring between the indoor side frame 1100 and the glass window 1400 and improving a heat insulation effect.

Next, a second embodiment of a thermal break door and window frame according to the present invention will be explained with reference to fig. 8.

The outdoor-side frame, the heat insulation frame, and the indoor-side frame of the heat insulated window and door frame according to the present embodiment are coupled by the first coupling member, and the glass window disposed between the outdoor-side frame and the indoor-side frame is fixed by the heat insulation block, the buffer material, and the second silicone coupling portion, which is the same as the first embodiment, and will not be described in detail here.

The indoor side frame of the thermal door window frame according to the embodiment includes a frame body, an adapter, a second coupling member, and a cover.

The frame body includes prefabricated square pipes, combination rods, molded rods, etc., which have been widely used as frames in the field.

The adaptor portion 2110 is connected to the frame body portions 2150, 2160, 2170 and the heat insulation frame 2300, and the heat insulation frame slots 2111, 2112 and the first protrusion 2113 described in the first embodiment are formed at the upper end of the adaptor portion 2110.

As shown in fig. 8 a and B, when the frame body part is formed of the square pipe 2150 and the combination rod 2160, the lower end of the adaptor 2110 is disposed to face the upper ends of the frame body parts 2150 and 2160, and the second coupling member B2 is coupled to the frame body parts 2150 and 2160 through the adaptor 2110.

At this time, the second coupling member B2 is coupled between the heat insulation frame notch 2111, 2112 formed in the adapter portion 2110 and the first protrusion 2113.

Of course, when the adaptor portion 2110 and the frame body portions 2150 and 2160 are structurally fixed by insertion coupling or by an adhesive, the second coupling member B2 may be omitted.

The cover portions 2114 and 2124 are disposed between the heat insulation frame notch 2111 and 2112 and the first protrusion 2113, and coupled to the adapting portion 2110 to cover the second coupling member B2 so that the second coupling member B2 is not exposed to the outside.

The adaptor in this embodiment is not limited thereto, and as described in fig. 8 c, when the frame body part is formed of a molding rod 2170, a structure 2120 for coupling with the frame body part 2170 may be formed at a lower end of the adaptor 2120.

Next, a third embodiment of a thermal break door and window frame according to the present invention will be explained with reference to fig. 9.

The outdoor side frame 3200, the heat insulation frame 3300 and the indoor side frame 3100 of the heat insulated door and window frame according to the present embodiment are coupled by the first coupling member B1, and the glass window 3400 disposed between the outdoor side frame 3200 and the indoor side frame 3100 is fixed by the heat insulation block 3500, the buffer material 3610 and the second silicone coupling portion 3620, which is the same as the first embodiment and will not be described in detail herein.

However, in the indoor side frame 3100 of the thermal break door window frame according to the present embodiment, a third protrusion 3105 extending from both sides of the lower end of the indoor side frame 3100 is protrudingly formed, and the indoor side frame 3100 includes a first structural reinforcement 3701, a cover portion 3703, and a second structural reinforcement 3702.

The first structural reinforcement 3701 is inserted into the third protrusion 3105 or at least one position between the upper end of the indoor side frame 3100 and the heat insulation block 3500, and is coupled to the indoor side frame 3100, thereby reinforcing the structure by increasing the tensile strength of the indoor side frame 3100.

Further, since the first structural reinforcement 3701 is made of reinforcing fibers such as carbon fibers and glass fibers, it is possible to expect a tensile strength increasing effect stronger than that of iron, and to reduce the weight of the thermal door window frame of the present invention compared to a structural reinforcement made of iron, so that the thermal door window frame of the present invention can be made lightweight and have a large tensile strength.

For example, when the first structural reinforcement 3701 is made of carbon fiber, the compression force and the tension force are about 10 times that of iron and about 30 times that of aluminum, and the specific gravity is light and about 1/10 times that of iron and about 1/3 times that of aluminum, so that the structural performance of the first structural reinforcement 3701 may be more excellent.

The cover 3703 is inserted inside the third protrusion 3105 and is disposed outside the first structural reinforcement 3701, preventing the first structural reinforcement 3701 from being exposed. The cover 3703 is disposed outside the first structural reinforcement 3701, which not only prevents the first structural reinforcement 3701 from being corroded, but also creates an environment and improves aesthetic quality when the cover 3703 is composed of an Organic Light Emitting Diode (OLED) or a design plate.

The second structural reinforcement 3702 is inserted into the interior of the indoor side frame 3100, coupled to the indoor side frame 3100, and perpendicular to the first structural reinforcement 3701, and the second structural reinforcement 3702 is provided to improve tensile strength of the indoor side frame 3100, and the number and thickness of the second structural reinforcement may be adjusted according to structural performance, and inserted into the indoor side frame 3100.

At this time, the second structural reinforcement 3702 may be composed of a metal material such as iron, aluminum, SUS, or the like.

Next, a fourth embodiment of the thermal break door and window frame of the present invention will be explained with reference to fig. 10 to 11.

The outdoor side frame 4200, the heat insulating frame 4300, and the indoor side frame 4100 of the heat insulated window and door frame according to the present embodiment are coupled by the first coupling member, and the window glass 1400 disposed between the outdoor side frame 4200 and the indoor side frame 4100 is fixed by the heat insulating block, the buffer material, and the second silicone coupling portion, which is the same as the first embodiment, and will not be described in detail here.

However, both side surfaces of the lower end portion of the indoor side frame 4100 of the insulated door and window frame according to the present embodiment are formed with the first fastening groove 4106, and the insulated door and window frame according to the present embodiment further includes the illumination portion 4800.

A first fastening protrusion 4801 coupled to the first fastening groove 4106 is formed at an upper end of the illumination unit 4800, and an electronic component accommodation unit is formed at a lower end thereof.

As shown in fig. 11, the electronic component housing part includes an outer electronic component housing part 4802 and an inner electronic component housing part 4803, a Printed Circuit Board (PCB)4804, an illumination 4805, and a light guide plate 4806 are provided from the inside to the outside between the outer electronic component housing part 4802 and the inner electronic component housing part 4803, and an illumination diffusion part 4807 is coupled between the ends of the outer electronic component housing part 4802, whereby the illumination part 4800 can create an environment and improve aesthetic quality.

The lighting part 4800 according to the present embodiment may be replaced with the second outdoor-side frame and combined with the first outdoor-side frame.

As described above, the present invention is not limited to the specific preferred embodiments, and various modifications can be made by those skilled in the art within the scope not exceeding the gist of the present invention claimed in the claims.

Industrial applicability

The present invention is applicable to a heat-insulated door/window frame in which a double-glazed window mostly using double glazing is supported by a heat-insulating block to reduce the thermal conductivity transmitted from an outdoor side frame and an indoor side frame to the window in doors and windows constructed in halls, schools, hospitals, businesses, or the like, which have certain requirements for heat insulation or sound insulation.

Claims (8)

1. An insulated door and window frame for supporting a glass window partitioning the interior and exterior of a building, the insulated door and window frame comprising:

an indoor side frame supporting the glass window inside a building;

an outdoor-side frame supporting the glass window at the outside of the building;

an insulation frame disposed between the indoor and outdoor side frames and supporting the glass window; and

a heat insulating block disposed at a side of the heat insulating frame and supporting the glass window,

an insulation frame clamping groove for being combined with the insulation frame is formed at the upper end of the indoor side frame along the length direction of the indoor side frame,

the heat insulation frame clamping grooves comprise a first heat insulation frame clamping groove and a second heat insulation frame clamping groove which are formed in opposite directions,

a single heat insulation frame coupling protrusion formed at a lower end of the heat insulation frame to be coupled with the heat insulation frame catching groove, an end of the heat insulation frame coupling protrusion being bent in one direction to be coupled to the heat insulation frame catching groove in only one direction,

the insulation frame combining protrusion is selectively inserted into the first insulation frame catching groove or the second insulation frame catching groove,

the heat insulation frame is composed of a plurality of pieces and is disposed to be spaced apart from each other along a length direction of the indoor-side frame.

2. The insulated door and window frame of claim 1,

first protruding parts protruding from both side surfaces of an upper end of the indoor side frame are formed in the indoor side frame,

the heat insulation block is disposed between the first protrusion and the heat insulation frame, and the height of the heat insulation block is higher than that of the first protrusion.

3. The insulated door and window frame of claim 1,

and a first heat insulation frame connecting part for connecting the heat insulation frame is formed at the lower end of the outdoor side frame along the length direction of the outdoor side frame.

4. Thermal window and door frame according to claim 3,

the heat insulation frame includes:

an indoor side frame fastening structure body, the lower end of which forms the heat insulation frame combination protrusion, and the opposite surface of the heat insulation frame combination protrusion forms a fastening part combination groove; and

and an outdoor side frame fastening structure having a lower end formed with a fastening portion coupling protrusion for coupling with the fastening portion coupling groove, an upper end formed with a second heat insulation frame connection portion for connection with the first heat insulation frame connection portion, and the outdoor side frame fastening structure wrapping at least a portion of an outer side surface of the indoor side frame fastening structure.

5. The insulated door and window frame of claim 2,

the indoor side frame includes:

a frame body portion; and

an adapter part for combining the frame body part and the heat insulation frame,

and the heat insulation frame clamping groove and the first protruding part are formed at the upper end of the adapter part.

6. The insulated door and window frame of claim 1,

a third protrusion protruding from both side surfaces of a lower end of the indoor side frame is formed in the indoor side frame,

and further comprising:

a first structural reinforcement inserted into the inside of the third protrusion to be combined with the indoor side frame; and

a second structural reinforcement inserted inside the indoor side frame to be combined with the indoor side frame and perpendicular to the first structural reinforcement.

7. The insulated door and window frame of claim 1,

first fastening grooves are formed on both side surfaces of the lower end portion of the indoor side frame,

and further includes an illumination part including illumination therein and formed at an upper end with a first fastening protrusion for coupling with the first fastening groove.

8. The insulated door and window frame of claim 1, further comprising:

an exterior material provided along outer side surfaces of the indoor-side frame and the outdoor-side frame; and

and an adhesive agent disposed between the indoor-side frame and the exterior material or between the outdoor-side frame and the exterior material, and bonding the indoor-side frame and the exterior material or the outdoor-side frame and the exterior material.

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