KR102658156B1 - Curtain wall that can minimize condensation through heat exchange tubes - Google Patents

Abstract

In the present invention, since the first heat exchange tube is disposed in a fixed frame disposed on the outdoor side and the second heat exchange tube is disposed in a support frame disposed on the indoor side, the condensation heat/evaporation heat or evaporation heat/ It has the advantage of reducing the temperature difference between indoors and outdoors through condensation heat.

Description

Curtain wall that can minimize condensation through heat exchange tubes}

The present invention relates to a curtain wall, and more specifically, to a curtain wall that can actively minimize condensation through heat exchange tubes.

Generally, the walls of buildings such as buildings, for example, non-load-bearing walls such as curtain walls, are provided with window frames, and these window frames are formed in a long bar shape to form wall structures (e.g., windows or exterior panels of walls). ) supports.

Here, windows are installed on the wall of the building, called a curtain wall, to ensure visibility and function as indoor lighting using sunlight, and these windows are supported by window frames that are long in the horizontal or vertical direction.

Patent Document 1 shows a conventional curtain wall, which includes a curtain wall fixed frame installed inside the building, a finishing cap installed at a predetermined distance from the curtain wall fixed frame, and a connection between the curtain wall fixed frame and the finishing cap. It consists of an insulating box rail and an insulating bracket that are fixed and connected between the curtain wall fixing frame and the finishing cap, and a curtain wall that is inserted and joined into the spaced space between the curtain wall fixing frame and the finishing cap.

Here, the front and rear sides of the curtain wall are firmly inserted and fixed between the curtain wall fixing frame and the finishing cap by friction against a gasket coupled to the insulation bracket and the finishing cap, and in this state, the room, inside and outside space are divided so that the outside air flows into the inside. Prevents waste from flowing into or being discharged to the outdoors.

In particular, the curtain wall is made of a transparent material and allows outdoor sunlight to pass through, so that sunlight shines into the indoor space and functions as indoor lighting.

However, in Patent Document 1 as described above, when the temperature difference between the inside and the outside is severe, such as in the winter, a significant temperature difference occurs on the surface of the thin curtain wall, and as a result, moisture present in the indoor air is absorbed into the curtain wall. Condensation occurs, which rapidly condenses on the surface of the wall. Due to this condensation, a large amount of moisture generated on the surface of the curtain wall penetrates into the building, causing corrosion in the building. Corrosion of the building reduces the stability of the building, and causes corrosion of the building. , moisture accumulates on the curtain wall due to the temperature difference between the outside air, making it difficult to secure visibility, and the internal and external air with a significant temperature difference is transmitted to the corresponding surfaces, causing damage or damage to the curtain wall due to a decrease in the rigidity of the curtain wall. there is.

Republic of Korea Patent No. 10-1272471 Republic of Korea Patent No. 10-2185399 Republic of Korea Patent No. 10-1576595 Republic of Korea Patent No. 10-2373415 Republic of Korea Patent No. 10-1862134

The purpose of the present invention is to provide a curtain wall that can actively minimize condensation through heat exchange tubes.

The present invention includes a fixed frame 200 fixed to a structure; A support frame 300 coupled to the fixed frame 200 and disposed outside the fixed frame 200; A deco frame (100) assembled to the support frame (300), hiding the support frame and exposed to the outside; A glass assembly 150 fixed to and in close contact with the fixing frame 200 and the support frame 300; It includes a heat pump device (800) disposed on at least one of the fixed frame (200) or the support frame (300) to reduce the indoor/outdoor temperature difference,

The heat pump device 800 includes a compressor 810; A first heat exchange tube (820) inserted and disposed in the fixed frame (200); A second heat exchange tube (830) inserted and disposed in the support frame (300); a four-way valve 840 that selects and flows the refrigerant compressed in the compressor 810 into either the first heat exchange tube 820 or the second heat exchange tube 830; a first electronic expansion valve (850) that expands the refrigerant supplied to the first heat exchange tube (820); a second electronic expansion valve (860) that expands the refrigerant supplied to the second heat exchange tube (830); It includes an accumulator tube 870 disposed on the inlet side of the compressor 810 and filtering liquid refrigerant from the refrigerant flowing into the compressor 810,

The fixed frame 200 includes a bottom frame 210 disposed on the ground side; A top frame 220 disposed on the upper side opposite to the bottom frame 210; A first side frame 230 connecting the left sides of the bottom frame 210 and the top frame 220; It includes a second side frame 240 connecting the right sides of the bottom frame 210 and the top frame 220,

The glass assembly 150 is disposed between the bottom frame 210, the top frame 220, the first side frame 230, and the second side frame 240, and a bottom is placed inside the bottom frame 210. A frame space 210a is formed, a top frame space 220a is formed inside the top frame 220, and a first side frame space 230a is formed inside the first side frame 230. , a second side frame space 240a is formed inside the second side frame 240,

The support frame 300 includes a bottom supporter 310 coupled to the bottom frame 210; A top supporter 320 coupled to the top frame 220; A first side supporter 330 coupled to the first side frame 230; It includes a second side supporter 340 coupled to the second side frame 240,

The first heat exchange tube 820 includes a 1-1 heat exchange tube 821 disposed on the bottom supporter 310; A 1-2 heat exchange tube 822 connected to the 1-1 heat exchange tube 821 and disposed on the first side supporter 330; A curtain wall including a 1-3 heat exchange tube 823 connected to the 1-2 heat exchange tube 822 and disposed on the top supporter 320 is provided.

First, in the present invention, since the first heat exchange tube is disposed in a fixed frame disposed on the outdoor side and the second heat exchange tube is disposed in a support frame disposed on the indoor side, the condensation heat/evaporation heat generated in the first heat exchange tube or It has the advantage of reducing the temperature difference between indoors and outdoors through heat of evaporation/condensation.

Second, in the present invention, since the first heat exchange tube disposed on the outdoor side is disposed inside the fixed frame, heat can be directly transferred through heat conduction to heat or cool the fixed frame, and the temperature difference between indoor and outdoor can be effectively resolved. There is an advantage.

Third, the present invention has the advantage of being able to eliminate indoor and outdoor temperature differences by operating the thermoelectric module placed inside the fixed frame, thereby minimizing condensation.

Fourth, there is an advantage of producing electricity by installing a solar panel on the front of the deco panel, storing the produced electricity in a battery placed inside the deco panel, and operating the thermoelectric module using the power stored in the battery. .

Fifth, the present invention has the advantage of being able to independently resolve condensation without additional cost because it stores electricity produced through solar power during the day and operates the thermoelectric module using the stored electricity.

Sixth, in the present invention, since the second heat exchange tube is disposed in direct contact with the second heat dissipation fin of the thermoelectric module, condensation and evaporation of the refrigerant through heat absorption/heat dissipation generated in the thermoelectric module and condensation heat/evaporation heat generated in the second heat exchange tube. It has the advantage of being able to promote effectively.

Seventh, in the present invention, since the fastening member penetrates the bottom supporter and the bottom deco body at the same time and is fastened to the battery during the installation process of the support frame and deco frame, the battery can be prevented from moving inside the bottom deco body, and three There is an advantage in that configurations can be combined at the same time.

1 is a front view of a curtain wall according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along AA shown in FIG. 1.
FIG. 3 is a cross-sectional view taken along BB shown in FIG. 1.
FIG. 4 is a partially enlarged view showing the bottom frame of FIG. 2.
Figure 5 is a partially enlarged view showing the top frame of Figure 2.
FIG. 6 is a partially enlarged view showing the first side frame of FIG. 3.
FIG. 7 is a partially enlarged view showing the second side frame of FIG. 3.
Figure 8 is a cross-sectional view showing the structures of the bottom supporter and top supporter shown in Figure 4 or 5.
Figure 9 is a cross-sectional view showing the structure of the side supporter shown in Figure 6 or Figure 7.
Figure 10 is a cross-sectional view showing a thermoelectric module according to the first embodiment of the present invention.
Figure 11 is a perspective view of the thermoelectric module shown in Figure 10.
Figure 12 is a schematic configuration diagram of a heat pump device according to the first embodiment of the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely provided to ensure that the disclosure of the present invention is complete and to be understood by those skilled in the art in the technical field to which the present invention pertains. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Figure 1 is a front view of a curtain wall according to a first embodiment of the present invention, Figure 2 is a cross-sectional view cut along A-A shown in Figure 1, and Figure 3 is a cross-sectional view cut along B-B shown in Figure 1, FIG. 4 is a partially enlarged view showing the bottom frame of FIG. 2, FIG. 5 is a partially enlarged view showing the top frame of FIG. 2, and FIG. 6 is a partially enlarged view showing the first side frame of FIG. 3. Figure 7 is a partially enlarged view showing the second side frame of Figure 3, Figure 8 is a cross-sectional view showing the structures of the bottom supporter and top supporter shown in Figure 4 or Figure 5, and Figure 9 is Figure 6 or Figure 7. is a cross-sectional view showing the structure of the side supporter shown in, Figure 10 is a cross-sectional view showing the thermoelectric module according to the first embodiment of the present invention, Figure 11 is a perspective view of the thermoelectric module shown in Figure 10, and Figure 12 is This is a schematic configuration diagram of a heat pump device according to the first embodiment of the present invention.

The curtain wall according to this embodiment includes a fixed frame 200 fixed to the structure, a support frame 300 coupled to the fixed frame 200 and disposed outside the fixed frame 200, and the support A deco frame 100 assembled to the frame 300 and exposed to the outside, a glass assembly 150 fixed in close contact with the fixed frame 200 and the support frame 300, and the fixed frame 200 or It includes a thermoelectric module 600 disposed on at least one of the support frames 300 and a heat pump device 800 disposed on at least one of the fixed frame 200 or the support frame 300.

The thermoelectric module 600 can actively eliminate the temperature difference between indoors and outdoors by generating heat on one side and cooling the other side through the applied power, and through this, the fixing frame 200, the support frame 300, or the glass assembly. Condensation occurring in at least one of (150) can be actively suppressed.

In addition, the heat pump device 800 circulates the refrigerant through the fixed frame 200 and the support frame 300 to condense and evaporate it, thereby actively reducing the temperature difference between the indoor and outdoor sides.

The fixed frame 200 includes a bottom frame 210 disposed on the ground side, a top frame 220 disposed on the upper side opposite to the bottom frame 210, and the bottom frame 210 and the top frame ( It includes a first side frame 230 connecting the left side of the bottom frame 220, and a second side frame 240 connecting the right side of the bottom frame 210 and the top frame 220.

The glass assembly 150 is disposed between the bottom frame 210, the top frame 220, the first side frame 230, and the second side frame 240, and the glass assembly 150 is connected to the bottom frame ( 210), the top frame 220, the first side frame 230, and the second side frame 240.

The curtain wall according to this embodiment may further include a solar panel device 400 disposed on at least one of the glass assembly 150 or the decor frame 100.

The bottom frame 210, top frame 220, first side frame 230, and second side frame 240 may all be fixed to the structure of the building.

The bottom frame 210 and the top frame 220 are formed to be longer in width than height. The first side frame 230 and the second side frame 240 are formed to be longer in height than width.

In this embodiment, the bottom frame 210 and the top frame 220 are fixed to the structure, and the first side frame 230 and the second side frame 340 are connected to the bottom frame 210 and the top frame 220. are combined. In this embodiment, the fixing frame 200 is integrated and fixed to the structure of the building, thereby shortening the installation time.

In this embodiment, the bottom frame 210, top frame 220, first side frame 230, and second side frame 240 are all manufactured in the form of square tubes with an empty interior.

The bottom frame 210 includes a front side 211, a back side 212, a left side 213, a right side (not shown), an upper side 215, and a lower side 216. A bottom frame space 210a is formed inside.

The left side 213 and the right side may be coupled to the first side frame 230 or the second side frame 240 through a fastening member 208.

The top frame 220 includes a front side 221, a back side 222, a left side 223, a right side (not shown), an upper side 215, and a lower side 216. A top frame space 220a is formed inside.

The left side 223 and the right side may be coupled to the first side frame 230 or the second side frame 240 through a fastening member 209.

The first side frame 230 includes a front 231, a back 232, a left side 233, a right side 234, an upper side (not shown), and a lower side 236. A first side frame space 230a is formed inside 230.

The second side frame 240 includes a front 241, a rear 242, a left side 243, a right side 244, an upper surface (not shown), and a lower surface 246. A second side frame space 240a is formed inside 240.

A fixed coupling portion 250 is disposed on the bottom frame 210, the top frame 220, the first side frame 230, and the second side frame 240, respectively. Each configuration of the fixed coupling portion 250 is the same, and the installation positions are different. If it is necessary to distinguish each configuration of the fixed coupler 250, the bottom fixed coupler 251, the top fixed coupler 252, the first side fixed coupler 253, or the second side fixed coupler 254. ).

The bottom fixed coupler 251, the top fixed coupler 252, the first side fixed coupler 253, and the second side fixed coupler 254 are connected to the bottom frame 210, the top frame 220, It is disposed on each front side of the first side frame 230 and the second side frame 240 and protrudes forward.

The glass assembly 150 may be disposed between the bottom fixed coupler 251, the top fixed coupler 252, the first side fixed coupler 253, or the second side fixed coupler 254, A portion of the load of the glass assembly 150 may be distributed to the bottom fixed coupler 251, the top fixed coupler 252, the first side fixed coupler 253, or the second side fixed coupler 254. there is.

The glass assembly 150 is attached to each front surface 211, 221, 231, 241 of the bottom frame 210, top frame 220, first side frame 230, and second side frame 240. can be closely adhered to.

An inter-frame space 205 is formed between the bottom frame 210, the top frame 220, the first side frame 230, and the second side frame 240. The inter-frame space 205 is disposed behind the glass assembly 150.

Since the structures of the bottom fixed coupler 251, the top fixed coupler 252, the first side fixed coupler 253, and the second side fixed coupler 254 are the same, the fixed coupler 250 The structure is explained by referring to .

The bottom fixed coupling portion 251 includes a bottom support wall 261 disposed to be retreated from the front 211 toward the rear 212, protrudes forward from the bottom support wall 261, and includes the support frame 300. It includes a bottom support column 271 coupled to a bottom support column 271 and a bottom coupling groove 281 concavely formed toward the rear side of the bottom support column 271.

The bottom support wall 261 is arranged vertically. The bottom support wall 261 is disposed to be retreated toward the rear surface 212 by the bottom coupling interval 219. The upper and lower ends of the bottom support wall (261) are connected to the front (211).

A bottom assembly groove 291 is formed between the bottom support wall 261 and the front surface 211.

The bottom support column 271 may be arranged horizontally and perpendicular to the bottom support wall 261. The bottom support column 271 may be horizontally placed in the middle of the height of the bottom frame 210.

The front end of the bottom support column 271 protrudes forward from the front surface 211 and may be inserted into the support frame 300.

The bottom coupling groove 281 is formed concavely from the front end of the bottom support column 271 to the rear. The bottom coupling groove 281 is disposed in the middle of the height of the bottom frame 210, and may be horizontally disposed to bisect the bottom wall 261.

The rear end of the bottom coupling groove 281 is disposed ahead of the bottom support wall 261, and is concave up to the bottom coupling gap 219 in this embodiment.

The structure of the top fixed coupler 252 is the same as that of the bottom fixed coupler 251.

The top fixed coupling portion 252 includes a top support wall 262 that is disposed to retreat from the front side 221 toward the back side 222, protrudes forward from the top support wall 262, and supports the support frame 300. ) and a top support column 272 coupled to the top support column 272, and a top coupling groove 282 concavely formed toward the rear of the top support column 272.

A top assembly groove 292 is formed between the top support wall 262 and the front surface 221.

The first side fixing coupler 253 includes a first side support wall 263 that is disposed to retreat from the front side 231 toward the back side 232, and protrudes forward from the first side support wall 263. , It includes a first side support column 273 coupled to the support frame 300, and a first side coupling groove 283 concavely formed toward the rear of the first side support column 273.

A first side assembly groove 293 is formed between the first side support wall 263 and the front surface 231.

The second side fixing coupler 254 includes a second side support wall 264 disposed to retreat from the front side 241 toward the back side 242, and protrudes forward from the second side support wall 264. , It includes a second side support column 274 coupled to the support frame 300, and a second side coupling groove 284 concavely formed toward the rear of the second side support column 274.

A second side assembly groove 294 is formed between the second side support wall 264 and the front surface 241.

The support frame 300 is coupled to a bottom supporter 310 coupled to the bottom frame 210, a top supporter 320 coupled to the top frame 220, and the first side frame 230. It includes a first side supporter 330 and a second side supporter 340 coupled to the second side frame 240.

In this embodiment, the bottom supporter 310, top supporter 320, first side supporter 330, and second side supporter 340 have the same structure, but their installation positions and directions are different.

The bottom supporter 310, top supporter 320, first side supporter 330, and second side supporter 340 may be formed of a metal material, and may receive heat from the thermoelectric module 600 through conduction. You can.

The bottom supporter 310 includes a first bottom support base 311 and a second bottom support base 312 that are inserted into the bottom assembly groove 291 and arranged to be spaced apart from each other, and the first bottom support base ( A first bottom support body 313 protruding forward from the second bottom support base 311), a second bottom support body 314 protruding forward from the second bottom support base 312, and the first bottom support body 313. and a bottom connection body 315 connecting the second bottom support body 314, disposed at the front end of the first bottom support body 313 and the second bottom support body 314, and the deco frame 100. and a bottom deco coupling portion 316 to be assembled, disposed on the rear side of the first bottom support body 313 and the second bottom support body 314, and inserted into and coupled to the bottom coupling groove 281. It is disposed between the bottom coupling protrusion 318 and the first bottom support base 311 and the second bottom support base 312, and includes a bottom column groove 319 into which the bottom support column 271 is inserted. .

The first bottom support base 311 and the second bottom support base 312 are arranged in a row. In this embodiment, the first bottom support base 311 is placed on the upper side, and the second bottom support base 312 is placed on the lower side.

The first bottom support base 311 and the second bottom support base 312 form mutual locks with the bottom assembly groove 291.

The bottom assembly groove 291 includes an upper bottom assembly groove 291a disposed on the upper side of the bottom support column 271 and a lower bottom assembly groove 291b disposed on the lower side of the bottom support column 291. do.

The protrusion 311a of the first bottom support base 311 forms a mutual lock with the upper bottom assembly groove 291a, and the protrusion 312a of the second bottom support base 312 forms the lower bottom assembly groove. It forms a mutual trap with (291b).

The protrusions 311a and 312a form mutual locks in the front-back direction and the up-down direction.

The first bottom support base 311 and the first bottom support body 313 are orthogonal to each other, and the second bottom support base 312 and the second bottom support body 314 are orthogonal to each other.

The first bottom support body 313 and the second bottom support body 314 are arranged in parallel. In this embodiment, the first bottom support body 313 is placed on the upper side, and the second bottom support body 314 is placed on the lower side.

The bottom connection body 315 couples the first bottom support body 313 and the second bottom support body 314, and is arranged in the vertical direction in this embodiment. The bottom connection body 315 may be disposed in multiple locations.

The bottom deco coupling portion 316 includes a first bottom deco coupling portion 316a extending from the first bottom support body 313, and a second bottom deco coupling portion extending from the second bottom support body 314. (316b), a first bottom stopping protrusion (317a) protruding from the first bottom deco coupling portion (316a) toward the second bottom deco coupling portion (316b), and a second bottom deco coupling portion (316b). It is formed between a second bottom stopping protrusion (317b) protruding in the direction of the first bottom deco coupling portion (316a), the first bottom deco coupling portion (316a) and the second bottom deco coupling portion (316b), and the deco It includes a bottom deco insertion groove 316c into which the frame 100 is inserted.

Some structures of the deco frame 100 may be inserted between the first bottom engaging protrusion 317a and the second bottom engaging protrusion 317b to secure the deco frame 100.

The bottom connection body 315 adjacent to the first bottom locking protrusion 317a and the second bottom locking protrusion 317b is provided with a bottom deformation portion 319 that can be elastically deformed by the elasticity of the material when the decor frame 100 is inserted. ) can be further placed.

In this embodiment, the bottom deformation portion 319 is formed in a “>” shape, and when inserting the deco frame 100, it can be opened in the vertical direction so that the deco frame 100 can be easily inserted.

In this embodiment, the bottom engaging protrusion 318 is disposed in the bottom column groove 319, and the bottom engaging protrusion 318 is hidden inside the bottom supporter 310 to be protected from external shock.

When the bottom coupling protrusion 318 is inserted and coupled to the bottom coupling groove 281, the bottom support column 271 is in close contact with the first bottom support base 311 and the second bottom support base 312. and is supported.

The top supporter 320 has the same structure as the bottom supporter 310.

The top supporter 320 includes a first top support base 321 and a second top support base 322 that are inserted into the top assembly groove 292 and arranged to be spaced apart from each other, and the first top support base ( 321), a first top support body 323 protruding forward, a second top support body 324 protruding forward from the second top support base 322, and the first top support body 323. and a top connection body 325 connecting the second top support body 324, disposed at the front end of the first top support body 323 and the second top support body 324, and the deco frame 100. and the assembled top deco coupling portion 326, which is disposed on the rear side of the first top support body 323 and the second top support body 324 and is inserted into and coupled to the top coupling groove 282. It is disposed between the top coupling protrusion 328 and the first top support base 321 and the second top support base 322, and includes a top column groove 329 into which the top support column 272 is inserted. .

The top assembly groove 292 includes an upper top assembly groove 292a disposed on the upper side of the top support column 272 and a lower top assembly groove 292b disposed on the lower side of the top support column 272. do.

The protrusion 321a of the first top support base 321 forms a mutual lock with the upper top assembly groove 292a, and the projection 322a of the second top support base 322 forms the lower top assembly groove. It forms a mutual trap with (292b).

The top deco coupling portion 326 includes a first top deco coupling portion 326a extending from the first top support body 323, and a second top deco coupling portion extending from the second top support body 324. (326b), a first top stopping protrusion (327a) protruding from the first top deco coupling portion (326a) toward the second top deco coupling portion (326b), and a second top deco coupling portion (326b). It is formed between a second top stopping protrusion (327b) protruding in the direction of the first top deco coupling portion (326a), the first top deco coupling portion (326a) and the second top deco coupling portion (326b), and the deco It includes a top deco insertion groove 326c into which the frame 100 is inserted.

The top connection body 325 adjacent to the first top locking protrusion 327a and the second top locking protrusion 327b is provided with a top deformation portion 329 that can be elastically deformed by the elasticity of the material when the deco frame 100 is inserted. ) can be further placed.

In this embodiment, the top deformation portion 329 is formed in a “>” shape, and when inserting the deco frame 100, it can be opened in the vertical direction so that the deco frame 100 can be easily inserted.

The first side supporter 330 includes a 1-1 side support base 331 and a 1-2 side support base 332 that are inserted into the first side assembly groove 293 and are spaced apart from each other. , a 1-1 side support body 333 protruding forward from the 1-1 side support base 331, and a 1-2 side protruding forward from the 1-2 side support base 332. A support body 334, a first side connection body 335 connecting the 1-1 side support body 333 and the 1-2 side support body 334, and the 1-1 side support body (333) and a first side deco coupling portion 336 disposed at the front end of the 1-2 side support body 334 and assembled with the deco frame 100, and the 1-1 side support body ( 333) and a first side coupling protrusion 338 disposed on the rear side of the 1-2 side support body 334 and inserted into and coupled to the first side coupling groove 283, and the 1-1 side It is disposed between the support base 331 and the 1-2 side support base 332, and includes a first side column groove 339 into which the first side support column 273 is inserted.

The first side assembly groove 293 includes a first left side assembly groove 293a disposed on the left side of the first side support column 273, and a first left side assembly groove 293a disposed on the right side of the first side support column 273. 1 Includes a right side assembly groove (293b).

The protrusion 331a of the 1-1 side support base 331 forms a mutual lock with the first left side assembly groove 293a, and the protrusion 332a of the 1-2 side support base 332 forms mutual locking with the first right side assembly groove (293b).

The first side deco coupling portion 336 includes a 1-1 side deco coupling portion 336a extending from the 1-1 side support body 333, and a 1-1 side deco coupling portion 336a extending from the 1-2 side support body 334. An extended 1-2 side deco coupling portion (336b) and a 1-1 side locking protrusion protruding from the 1-1 side deco coupling portion (336a) toward the 1-2 side deco coupling portion (336b). (337a), a 1-2 side stopping protrusion (337b) protruding from the 1-2 side deco coupling portion (336b) toward the 1-1 side deco coupling portion (336a), and the 1-1 It is formed between the side deco coupling portion 336a and the 1-2 side deco coupling portion 336b, and includes a first side deco insertion groove 336c into which the decor frame 100 is inserted.

The first side connection body 335 adjacent to the 1-1 side locking protrusion 337a and the 1-2 side locking protrusion 337b may be elastically deformed due to the elasticity of the material when the decor frame 100 is inserted. A first side deformation portion 339 may be further disposed.

In this embodiment, the first side deformation portion 339 is formed in a “∧” shape, and when inserting the deco frame 100, it can be opened in the left and right directions so that the deco frame 100 can be easily inserted. there is.

The second side supporter 340 includes a 2-1 side support base 341 and a 2-2 side support base 342 that are inserted into the second side assembly groove 294 and are spaced apart from each other. , a 2-1 side support body 343 protruding forward from the 2-1 side support base 341, and a 2-2 side protruding forward from the 2-2 side support base 342. A support body 344, a second side connection body 345 connecting the 2-1 side support body 343 and the 2-2 side support body 344, and the 2-1 side support body (343) and a second side deco coupling portion 346 disposed at the front end of the 2-2 side support body 344 and assembled with the deco frame 100, and the 2-1 side support body ( 343) and a second side coupling protrusion 348 disposed on the rear side of the 2-2 side support body 344 and inserted into and coupled to the second side coupling groove 284, and the 2-1 side It is disposed between the support base 341 and the 2-2 side support base 342, and includes a second side column groove 349 into which the second side support column 274 is inserted.

The second side assembly groove 294 includes a second left side assembly groove 294a disposed on the left side of the second side support column 274, and a second left side assembly groove 294a disposed on the right side of the second side support column 274. Includes 2 right side assembly grooves 294b.

The protrusion 341a of the 2-1 side support base 341 forms a mutual lock with the second left side assembly groove 294a, and the protrusion 342a of the 2-2 side support base 342 forms mutual locking with the second right side assembly groove (294b).

The second side deco coupling portion 346 includes a 2-1 side deco coupling portion 346a extending from the 2-1 side support body 343, and a 2-1 side deco coupling portion 346a extending from the 2-2 side support body 344. An extended 2-2 side deco coupling portion (346b) and a 2-1 side locking protrusion protruding from the 2-1 side deco coupling portion (346a) toward the 2-2 side deco coupling portion (346b). (347a), a 2-2 side stopping protrusion (347b) protruding from the 2-2 side deco coupling portion (346b) toward the 2-1 side deco coupling portion (346a), and the 2-1 It is formed between the side deco coupling portion 346a and the 2-2 side deco coupling portion 346b, and includes a second side deco insertion groove 346c into which the decor frame 100 is inserted.

The second side connection body 345 adjacent to the 2-1 side locking protrusion 347a and the 2-2 side locking protrusion 347b may be elastically deformed due to the elasticity of the material when the decor frame 100 is inserted. A second side deformation portion 349 may be further disposed.

In this embodiment, the fourth side deformation portion 349 is formed in a “∧” shape, and when inserting the deco frame 100, it can be opened in the left and right directions so that the deco frame 100 can be easily inserted. there is.

The decor frame 100 is coupled to the bottom decor 110 coupled to the bottom supporter 310, the top decor 120 coupled to the top supporter 320, and the first side supporter 330. It includes a first side decor 130 and a second side decor 140 coupled to the second side supporter 340.

The bottom deco 110 includes a first bottom deco body 112 disposed in front of the bottom supporter 310 and covering the front of the bottom supporter 310, and the first bottom deco body 112. A bottom deco coupling portion 116 is disposed and inserted into and fitted into the bottom deco insertion groove 316c, and is coupled to the first bottom deco body 112 and a lower side of the second bottom support body 314. It includes a second bottom deco body 114 that covers.

A bottom fitting member 710 may be further disposed between the second bottom deco body 114 and the front surface 211 of the bottom frame 210. The bottom fitting member 710 is preferably made of an elastic material.

The bottom fitting member 710 can cushion the space between the bottom deco 110 and the bottom supporter 310 and blocks external foreign substances from penetrating inside.

The bottom fitting member 710 has a front surface in close contact with the rear surface of the second bottom deco body 114, a rear surface in close contact with the front surface 211, and an upper surface in close contact with the second bottom support body 314. and the lower surface may be exposed to the outside.

A bottom deco fitting part 115 inserted into the bottom fitting member 710 may be further disposed in the second bottom deco body 114, and the bottom deco fitting part 115 is connected to the bottom fitting member 710. ) By being inserted and fixed inside, it is possible to block external foreign substances from penetrating into the bottom supporter 310.

The bottom supporter 310 includes a first bottom fastening member 361a penetrating the first bottom support base 311 and the upper bottom assembly groove 291a, the second bottom support base 312, and the lower bottom assembly. It can be fixed to the bottom frame 210 through the second bottom fastening member 361b penetrating the groove 291b.

The bottom supporter 310 and the bottom deco 110 include a third bottom fastening member 361c that penetrates the first bottom support body 313, the second bottom support body 314, and the second bottom deco body 114. ) can be combined through.

The lower end of the glass assembly 150 may be supported in close contact with the first bottom support body 313.

The top deco 120 includes a first top deco body 122 disposed in front of the top supporter 320 and covering the front of the top supporter 320, and the first top deco body 122. A top deco coupling portion 126 is disposed and inserted and fitted into the top deco insertion groove 326c, and is coupled to the first top deco body 122, and the upper side of the first top support body 323. It includes a second top deco body 124 that covers.

A top fitting member 720 may be further disposed between the second top deco body 124 and the front 221 of the top frame 220. The top fitting member 720 is preferably made of an elastic material.

The top fitting member 720 can cushion the space between the top deco 120 and the top supporter 320 and blocks external foreign substances from penetrating inside.

The top fitting member 720 has a front surface in close contact with the rear surface of the second top deco body 124, a rear surface in close contact with the front surface 221, and a bottom surface in close contact with the first top support body 323. And the upper surface can be exposed to the outside.

A top deco fitting part 125 inserted into the top fitting member 720 may be further disposed in the second top deco body 124, and the top deco fitting part 125 is connected to the top fitting member 720. ) By being inserted and fixed inside, it is possible to block external foreign substances from penetrating into the top supporter 320.

The top supporter 320 includes a first top fastening member 362a penetrating the first top support base 321 and the upper top assembly groove 292a, the second top support base 322, and the lower top assembly. It can be fixed to the top frame 220 through the second top fastening member 362b penetrating the groove 292b.

The top supporter 320 and top deco 120 are formed by a third top fastening member 362c that penetrates the first top support body 323, the second top support body 324, and the second top deco body 124. ) can be combined through.

The upper end of the glass assembly 150 may be supported in close contact with the first top support body 323.

The first side deco 130 includes a 1-1 side deco body 132 disposed in front of the first side supporter 330 and covering the front of the first side supporter 330, and the first side deco body 132. A first side deco coupling portion 136 disposed on the 1-1 side deco body 132 and inserted into and fitted into the first side deco insertion groove 336c, and the 1-1 side deco body 132 ) and includes a 1-2 side deco body 134 that covers the left side of the 1-1 side support body 333.

A first side fitting member 730 may be further disposed between the 1-2 side deco body 134 and the front 231 of the first side frame 230. The first side fitting member 730 is preferably made of an elastic material.

The first side fitting member 730 can cushion the space between the first side deco 130 and the first side supporter 330 and blocks external foreign substances from penetrating into the interior.

The first side fitting member 730 has a front surface in close contact with the rear surface of the 1-2 side deco body 134, a rear surface in close contact with the front surface 231, and a right side contact with the 1-1 side support. It is in close contact with the body 333, and the left side may be exposed to the outside.

A first side deco fitting part 135 inserted into the first side fitting member 730 may be further disposed in the 1-2 side deco body 134, and the first side deco fitting part 135 ) is inserted and fixed into the first side fitting member 730, thereby preventing external foreign substances from penetrating into the first side supporter 330.

The first side supporter 330 includes a 1-1 side fastening member 363a penetrating the 1-1 side support base 331 and the first left side assembly groove 293a, and the 1-2 side fastening member 363a. It can be fixed to the first side frame 230 through the 1-2 side fastening member 363b penetrating the side support base 332 and the first right side assembly groove 293b.

The first side supporter 330 and the first side decor 130 include the 1-2 side support body 334, the 1-1 side support body 333, and the 1-2 side decor body 134. It can be coupled through the first to third side fastening members (363c) that sequentially penetrate.

The left end of the glass assembly 150 may be supported in close contact with the 1-1 side support body 333.

The second side deco 140 includes a 2-1 side deco body 142 disposed in front of the second side supporter 340 and covering the front of the second side supporter 340, and the second side deco body 142. A second side deco coupling portion 146 disposed on the 2-1 side deco body 142 and inserted into and fitted into the second side deco insertion groove 346c, and the 2-1 side deco body 142 ) and includes a 2-2 side deco body 144 that covers the left side of the 2-1 side support body 343.

A second side fitting member 740 may be further disposed between the 2-2 side deco body 144 and the front surface 241 of the second side frame 240. The second side fitting member 740 is preferably made of an elastic material.

The second side fitting member 740 can cushion the space between the second side deco 140 and the second side supporter 340 and blocks external foreign substances from penetrating into the interior.

The second side fitting member 740 has a front surface in close contact with the rear surface of the 2-2 side deco body 144, a rear surface in close contact with the front surface 241, and a left surface in close contact with the 2-2 side. It is in close contact with the support body 344, and the right side may be exposed to the outside.

A second side deco fitting part 145 inserted into the second side fitting member 740 may be further disposed in the 2-2 side deco body 144, and the second side deco fitting part 145 ) is inserted and fixed into the second side fitting member 740, thereby preventing external foreign substances from penetrating into the second side supporter 340.

The second side supporter 340 includes a 2-1 side fastening member 364a penetrating the 2-1 side support base 341 and the second left side assembly groove 294a, and the 2-2 It can be fixed to the second side frame 240 through the 2-2 side fastening member 364b penetrating the side support base 342 and the second right side assembly groove 294b.

The second side supporter 340 and the second side decor 140 include the 2-1 side support body 343, the 2-2 side support body 344, and the 2-2 side decor body 144. It can be coupled through the 2nd and 3rd side fastening members 364c that sequentially penetrate.

The right end of the glass assembly 150 may be supported in close contact with the 1-1 side support body 333.

Referring to Figure 2 or Figure 3, the curtain wall according to this embodiment includes a solar panel 400 disposed on the front of the deco frame 100 and a battery disposed inside the support frame 300 ( 500) and a thermoelectric module 600 disposed inside the fixed frame 200.

The solar panel 400 includes a first solar panel 410 disposed in front of the bottom deco 110, a second solar panel 420 disposed in front of the top deco 120, and , a third solar panel 430 disposed in front of the first side decor 130, and a fourth solar panel 440 disposed in front of the second side decor 140.

The first solar panel 410 is arranged to cover the front surfaces of the first bottom deco body 112 and the second bottom deco body 114.

The second solar panel 420 is arranged to cover the front surfaces of the first top deco body 122 and the second top deco body 124.

The third solar panel 430 is arranged to cover the front surfaces of the 1-1 side deco body 132 and the 1-2 side deco body 134.

The fourth solar panel 440 is arranged to cover the front surfaces of the 2-1 side deco body 142 and the 2-2 side deco body 144.

An empty space of the first bottom deco space (112a) is formed inside the first bottom deco body 112, and an empty space of the second bottom deco space (114a) is formed inside the second bottom deco body 114. do.

An empty space of the first top deco space (122a) is formed inside the first top deco body 122, and an empty space of the second top deco space (124a) is formed inside the second top deco body 124. do.

An empty space of the 1-1 side deco space (132a) is formed inside the 1-1 side deco body 132, and a 1-2 side deco body is formed inside the 1-2 side deco body 134. An empty space in the decoration space 134a is formed.

An empty space of the 2-1 side deco space 142a is formed inside the 2-1 side deco body 142, and a 2-2 side deco body 144 is formed inside the 2-2 side deco body 144. An empty space in the decoration space 144a is formed.

Referring to FIGS. 4 to 7, the battery 500 includes a first battery 510 disposed inside the bottom deco 110 and storing power produced by the first solar panel 410. , a second battery 520 disposed inside the top deco 120 to store power produced by the second solar panel 420, and disposed inside the first side deco 130 to A third battery 530 stores the power produced by the third solar panel 430, and is disposed inside the second side deco 140 to store the power produced by the fourth solar panel 440. Includes a fourth battery 540 for storage.

Specifically, the first battery 510 is disposed in the second bottom deco space 114a, the second battery 520 is disposed in the second top deco space 124a, and the third battery 530 ) is disposed in the 1-2 side decor space (134a), and the fourth battery 540 is disposed in the 2-2 side decor space (144a).

Since the first bottom deco body 112 is disposed in front of the bottom supporter 310 and the second bottom deco body 114 is disposed on the side of the bottom supporter 310, the second bottom deco space (114a) is larger than the volume of the first bottom deco space (112a), and a sufficient installation space for the first battery 510 can be secured.

In particular, when installing the third bottom fastening member 361c, it is fastened to the first battery 510, so that the bottom deco 110, the bottom supporter 310, and the first battery 510 can be fixed at the same time. there is.

Since the first top deco body 122 is disposed in front of the top supporter 320 and the second top deco body 124 is disposed on the side of the top supporter 320, the second top deco space (124a) is larger than the volume of the first top deco space (122a), and a sufficient installation space for the second battery 520 can be secured.

When installing the third top fastening member 362c, it is fastened to the second battery 520, so that the top deco 120, top supporter 320, and second battery 520 can be fixed at the same time.

The 1-1 side deco body 132 is disposed in front of the first side supporter 330, and the 1-2 side deco body 134 is disposed on the side of the first side supporter 330. Therefore, the volume of the 1-2 side decor space 134a is larger than the volume of the 1-1 side decor space 132a, and a sufficient installation space for the third battery 530 can be secured.

When installing the 1-3 side fastening member 363c, it is fastened to the third battery 530, thereby making the first side deco 130, the first side supporter 330, and the third battery 530 Can be fixed at the same time.

The 2-1 side deco body 142 is disposed in front of the second side supporter 340, and the 2-2 side deco body 144 is disposed on the side of the second side supporter 340. Therefore, the volume of the 2-2 side decor space 144a is larger than the volume of the 2-1 side decor space 142a, and a sufficient installation space for the fourth battery 540 can be secured.

When installing the 2-3 side fastening member 364c, it is fastened to the fourth battery 540, thereby making the second side deco 140, the second side supporter 340, and the fourth battery 540 Can be fixed at the same time.

In this embodiment, the thermoelectric module 600 is placed inside the fixed frame 200, and specifically inside the bottom frame 210.

The thermoelectric module 600 may receive power through at least one of the first battery 510, second battery 520, third battery 530, or fourth battery 540.

The thermoelectric module 600 is a semiconductor that is operated by an applied power source to generate heat on one side and absorb heat on the other side.

The thermoelectric module 600 includes a thermoelectric element 650 operated by an applied power source, a first heat dissipation fin 610 disposed on one side of the thermoelectric element 650, and another heat dissipation fin 610 of the thermoelectric element 650. It includes a second heat dissipation fin 620 disposed on the side.

The thermoelectric element is largely a thermistor, which is a device that uses temperature changes in electrical resistance, a device that uses the Seebeck effect, a phenomenon in which electromotive force is generated by a temperature difference, and a device that uses the Peltier effect, a phenomenon in which heat is absorbed (or generated) by current. There are devices such as Peltier devices.

A thermistor is a type of semiconductor device whose electrical resistance changes significantly depending on temperature. A thermistor is a negative temperature coefficient thermistor (NTC) whose electrical resistance decreases as the temperature increases, and a positive temperature coefficient thermistor (PTC) whose resistance increases as the temperature increases. positive temperature coefficient thermistor), etc. are used.

Thermistors are made by mixing oxides such as molybdenum, nickel, cobalt, and iron into multiple components and sintering them, and are used for stabilizing circuits and detecting heat, power, and light.

The Peltier effect is a phenomenon in which when two types of metal ends are connected and current flows, one terminal absorbs heat and the other terminal generates heat depending on the direction of the current. If you use semiconductors such as bismuth and tellurium, which have different electrical conduction methods, instead of two types of metals, you can obtain a Peltier device that has highly efficient heat absorption and heat generation functions.

This allows switching between heat absorption and heat generation depending on the direction of the current, and the amount of heat absorption and heat generation is adjusted depending on the amount of current, so it is applied to the production of low-capacity refrigerators or precise constant temperature baths near room temperature.

Since the structure of the thermoelectric element using the Peltier effect is a common technique for those skilled in the art, detailed description is omitted.

The thermoelectric module 600 is disposed in the bottom frame space 210a where the thermoelectric element 650, the first heat radiation fin 610, and the second heat radiation fin 620 are formed inside the bottom frame 210.

The thermoelectric module 600 has a first heat dissipation fin 610, a thermoelectric element 650, and a second heat dissipation fin 620 arranged horizontally, and the thermoelectric element 650 includes the first heat dissipation fin 610 and a second heat dissipation fin ( 620).

In this embodiment, the first heat dissipation fin 610 is disposed on the front side, and the second heat dissipation fin 620 is disposed on the rear side. The first heat dissipation fin 610 and the second heat dissipation fin 620 may be formed by stacking multiple fins.

The first heat dissipation fin 610 and the second heat dissipation fin 620 are arranged in close contact with the inner surface of the bottom frame 210 and have the characteristic of conducting heat directly to the bottom frame 210.

The front of the first heat dissipation fin 610 is in close contact with the bottom support wall 261, and the back of the second heat dissipation fin 620 is in contact with the back surface 212 of the bottom frame 210 to conduct heat. .

In this embodiment, the 1-1 radiating fin fastening hole 611 and the 1-2 radiating fin are fastened to the first radiating fin 610 with the first bottom fastening member 361a and the second bottom fastening member 361b. A fastening hole 612 may be formed.

The first bottom fastening member 361a penetrates the first bottom support base 311 and the bottom support wall 261 and is inserted into the 1-1 heat dissipation fin fastening hole 611 to form the first heat dissipation fin 610. It can be combined with .

The second bottom fastening member 361b penetrates the second bottom support base 312 and the bottom support wall 261 and is inserted into the 1-2 heat dissipation fin fastening hole 612 to connect the first heat dissipation fin 610. It can be combined with .

In this embodiment, the bottom supporter 310, the bottom frame 210, and the first heat dissipation fin 610 are connected to the first bottom fastening member 361a through the first bottom fastening member 361a or the second bottom fastening member 361b. ) has the advantage of being able to be combined at once.

In addition, since the first bottom fastening member 361a and the second bottom fastening member 361b are made of a metal material, the heat of the first heat dissipation fin 610 will be transferred to the bottom supporter 310 through conduction. You can.

Since the bottom fitting member 710 is made of an elastic material with low thermal conductivity, heat conduction of the second bottom deco body 114 and the second bottom support base 312 that are in direct contact with the outside air can be blocked, and through this, The rapid temperature change of the bottom supporter 310 can be delayed or reduced.

In addition, dew formation on the bottom supporter 310 can be minimized or prevented through heat generation from the first battery 510 disposed inside the second bottom deco body 114.

When the thermoelectric element 650 operates, heat is generated in the first heat radiation fin 610, heat is generated in the second heat radiation fin 620, and heat is generated in the first heat radiation fin 610. , heat absorption is generated in the second heat dissipation fin 620.

During the day when solar power is supplied, the temperature difference between the outside and inside of the curtain wall is small, so the amount and frequency of condensation are low. At night when solar power is not provided, there is a large temperature difference between indoors and outdoors, and condensation may occur on the indoor side where the temperature is high.

The electricity produced by the solar panel 400 is stored in the battery 500, and the thermoelectric module 600 according to this embodiment is operated in a time zone where the temperature difference is large through the power of the battery 500, thereby creating a curtain wall. Condensation can be actively minimized.

The thermoelectric module 600 according to this embodiment can be operated not only in winter, when condensation mainly occurs, but also in summer.

That is, electricity produced during the day is stored, and the temperature difference between indoors and outdoors can be reduced by operating the thermoelectric module 600 at night, when a large temperature difference is formed through the stored electricity.

The curtain wall according to this embodiment has the advantage of not having an additional burden on electricity costs because it does not use a separate external power source when operating the thermoelectric module 600.

Since the first battery 510, second battery 520, third battery 530, and fourth battery 540 are hidden inside the deco frame 100, the influence of the external environment can be minimized. , external damage can be prevented.

Meanwhile, the heat pump device 800 according to this embodiment includes a compressor 810, a first heat exchange tube 820 inserted into the fixed frame 200, and inserted into the support frame 300. a second heat exchange tube 830 disposed, and a four-way valve ( 840), a first electronic expansion valve 850 that expands the refrigerant supplied to the first heat exchange tube 820, and a second electronic expansion valve (850) that expands the refrigerant supplied to the second heat exchange tube 830 860) and an accumulator tube 870 that is disposed on the inlet side of the compressor 810 and filters liquid refrigerant from the refrigerant flowing into the compressor 810.

The compressor 810 may be operated using power from the batteries 510, 520, 530, and 540 or an external power source.

In this embodiment, the compressor 810 may be placed in the space between frames 205 and may be supported by being mounted on the bottom frame 210.

The first heat exchange tube 820 is disposed on the support frame 300.

The first heat exchange tube 820 is formed in a tube shape, and refrigerant can flow therein.

The first heat exchange tube 820 is disposed outside the second heat exchange tube 830.

The first heat exchange tube 820 is connected to the 1-1 heat exchange tube 821 disposed on the bottom supporter 310, and the 1-1 heat exchange tube 821, and is connected to the first side supporter ( 330), and a 1-3 heat exchange tube 823 connected to the 1-2 heat exchange tube 822 and disposed on the top supporter 320. .

Specifically, the 1-1 heat exchange tube 821 is disposed between the first bottom support body 313 and the second bottom support body 314, and the 1-2 heat exchange tube 822 is disposed between the first bottom support body 313 and the second bottom support body 314. -1 is disposed between the side support body 333 and the 1-2 side support body 334, and the 1-3 heat exchange tube 823 is connected to the first top support body 323 and the second top support body. It is placed between (324).

When the refrigerant condenses or evaporates inside the first heat exchange tube 820, the bottom supporter 310, the first side supporter 330, and the top supporter 320, which are made of metal, are heated by the heat of condensation or evaporation of the refrigerant. Alternatively, it can be cooled, and through this, the temperature of the support frame 300 and the decoration frame 100 can be adjusted to actively eliminate condensation due to the indoor and outdoor temperature difference.

The second heat exchange tube 830 is connected to the 2-1 heat exchange tube 831 disposed in the bottom frame 210, and the 2-1 heat exchange tube 831, and is connected to the first side frame ( 230), and a 2-3 heat exchange tube 833 connected to the 2-2 heat exchange tube 832 and disposed on the top frame 220. .

The second heat exchange tube 820 is formed in a tube shape, and refrigerant can flow therein.

Specifically, the 2-1 heat exchange tube 831 is disposed inside the first bottom frame 210 and is placed in contact with the second heat dissipation fin 620, and the 2-2 heat exchange tube 832 is disposed at the It is disposed inside the first side frame 230, and is disposed in contact with the first side frame 230, and the 2-3 heat exchange tube 833 is disposed through the inside of the top frame 220, It is placed in contact with the top frame 220.

Heat can be directly exchanged through conduction by contacting the 2-1 heat exchange tube 831 and the second heat dissipation fin 620. The 2-2 heat exchange tube 832 is in direct contact with the first side frame 230 and can transfer heat through conduction. The 2-3 heat exchange tube 833 is placed in contact with the top frame 220 and can transfer heat through conduction.

When the refrigerant condenses inside the first heat exchange tube 820, the support frame 300 is heated by the condensation heat of the refrigerant, and when the refrigerant evaporates inside the second heat exchange tube 830, the fixed frame (200) is cooled by the heat of evaporation of the refrigerant.

Conversely, when the refrigerant evaporates inside the first heat exchange tube 820, the support frame 300 is cooled by the heat of evaporation of the refrigerant, and when the refrigerant condenses inside the second heat exchange tube 830, the fixed The frame 200 is heated by the condensation heat of the refrigerant.

In this way, condensation heat/evaporation heat or evaporation heat/condensation heat is generated in the first heat exchange tube 820 and the second heat exchange tube 830 according to the circulation direction of the refrigerant, and through this, condensation due to the indoor and outdoor temperature difference can be actively eliminated. You can.

The accumulator tube 870 may be disposed inside the second side frame 240 and may be disposed to extend long in the above direction.

The four-way valve 840 may be disposed in the space between the frames 205 close to the compressor 810, and can select the flow direction of the refrigerant with the first heat exchange tube 820 or the second heat exchange tube 830. You can.

The first electronic expansion valve 850 and the second electronic expansion valve 860 may also be disposed in the space between the frames 205.

The heat pump device 800 may be operated when the temperature difference between indoors and outdoors is not reduced despite the thermoelectric module 600 being operated.

When heating the first heat exchange tube 820 and cooling the second heat exchange tube 830, the refrigerant compressed in the compressor 810 flows into the first heat exchange tube 820 through the four-way valve 840. ), and the refrigerant is condensed inside the first heat exchange tube 820 to heat the support frame 300.

The refrigerant condensed in the first heat exchange tube 820 is expanded in the first electronic expansion valve 850 and then evaporated inside the second heat exchange tube 830.

Afterwards, the evaporated refrigerant is returned to the compressor 810 through the accumulator tube 870 and can cycle through the above-described cycle.

When cooling the first heat exchange tube 820 and heating the second heat exchange tube 830, the refrigerant compressed in the compressor 810 flows into the second heat exchange tube 830 through the four-way valve 840. ), and the refrigerant is condensed inside the second heat exchange tube 830 to heat the fixed frame 200 and the second heat dissipation fin 620.

The refrigerant condensed in the second heat exchange tube 830 is expanded in the first electronic expansion valve 850 and then evaporated inside the first heat exchange tube 820.

Afterwards, the evaporated refrigerant is returned to the compressor 810 through the accumulator tube 870 and can cycle through the above-described cycle.

The heat pump device 600 can be operated when the temperature difference between the upper and lower sides of the room is large.

A person skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. The scope of the present invention is indicated by the scope of the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts are included in the scope of the present invention. must be interpreted.

101: first sliding door 102: second sliding door
200: Outer frame 210: Bottom frame
220: Top frame 230: First side frame
240: second side frame 250: first rail
260: 2nd rail 300: Bottom gap frame
400: Solar panel device 600: Thermoelectric module
650: thermoelectric element 610: first heat dissipation fin
620: Second heat dissipation fin 800: Heat pump device
810: Compressor 820: First heat exchange tube
830: Second heat exchange tube 840: Four-way valve
850: first electronic expansion valve 860: second electronic expansion valve
870: Accumulator tube

Claims (1)

A fixed frame 200 fixed to the structure;
A support frame 300 coupled to the fixed frame 200 and disposed outside the fixed frame 200;
A deco frame (100) assembled to the support frame (300), hiding the support frame and exposed to the outside;
A glass assembly 150 fixed to and in close contact with the fixing frame 200 and the support frame 300;
It includes a heat pump device (800) disposed on at least one of the fixed frame (200) or the support frame (300) to reduce the indoor/outdoor temperature difference,
The heat pump device 800,
Compressor (810);
A first heat exchange tube (820) inserted and disposed in the fixed frame (200);
A second heat exchange tube (830) inserted and disposed in the support frame (300);
a four-way valve 840 that selects and flows the refrigerant compressed in the compressor 810 into either the first heat exchange tube 820 or the second heat exchange tube 830;
a first electronic expansion valve (850) that expands the refrigerant supplied to the first heat exchange tube (820);
a second electronic expansion valve (860) that expands the refrigerant supplied to the second heat exchange tube (830);
It includes an accumulator tube 870 disposed on the inlet side of the compressor 810 and filtering liquid refrigerant from the refrigerant flowing into the compressor 810,
The fixed frame 200 is,
Bottom frame 210 disposed on the ground side; A top frame 220 disposed on the upper side opposite to the bottom frame 210; A first side frame 230 connecting the left sides of the bottom frame 210 and the top frame 220; It includes a second side frame 240 connecting the right sides of the bottom frame 210 and the top frame 220,
The glass assembly 150 is disposed between the bottom frame 210, the top frame 220, the first side frame 230, and the second side frame 240,
A bottom frame space 210a is formed inside the bottom frame 210,
A top frame space 220a is formed inside the top frame 220,
A first side frame space 230a is formed inside the first side frame 230,
A second side frame space 240a is formed inside the second side frame 240,
The support frame 300 is,
Bottom supporter 310 coupled to the bottom frame 210;
A top supporter 320 coupled to the top frame 220;
A first side supporter 330 coupled to the first side frame 230;
It includes a second side supporter 340 coupled to the second side frame 240,
The first heat exchange tube 820,
A 1-1 heat exchange tube 821 disposed on the bottom supporter 310;
A 1-2 heat exchange tube 822 connected to the 1-1 heat exchange tube 821 and disposed on the first side supporter 330;
A curtain wall comprising a 1-3 heat exchange tube (823) connected to the 1-2 heat exchange tube (822) and disposed on the top supporter (320).

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