KR101811016B1 - Window system - Google Patents

Abstract

The present invention relates to a window system and, more specifically, provides a window system which comprises: a window frame; an internal window installed at an indoor side of the window frame, and provided to be opened and closed from the window frame; and an external window fixated to the window frame, and spaced from the internal window to an outdoor side to form a hollow layer. In the external window, outdoor air flows into the hollow layer to form a flow path circulating in the inside of the hollow layer, and on the flow path, a flow rate control unit controlling a flow rate of the outdoor air flowing into the hollow layer is installed.

Description

Window system {Window system}

The present invention relates to a window system, and more particularly, to a window system capable of controlling a flow rate of outdoor air flowing into a hollow layer formed between an outer window and an inner window, thereby minimizing the loss of heat energy due to cooling / .

In recent years, due to the effect of global warming, the air conditioner has been lengthened, the surface area of the glass facade has increased, the office office OA equipment has increased, and the demand for indoor comfort has been continuously increased. There is a growing demand for solar radiation protection through solar radiation. In particular, this phenomenon is similar in most high-rise buildings.

Prior art for a conventional double skin window system is disclosed in Korean Patent No. 10-1010203 (2011.01.17) (Prior Art 1), in which a hollow layer is formed between double skin layers and a shade or a blind is provided on the hollow layer It is common to control solar incidence. In addition, since the hollow layer can be naturally ventilated, it is possible to discharge the overheating of the hollow layer by the solar radiation to the outside, thereby contributing to the cooling load reduction of the room.

However, in the prior art 1, when the bead is installed in the hollow layer, the width of the hollow layer is increased, and accordingly, the thickness of the double sheath also increases. This causes the construction cost to increase more than twice as much as that of the single jacket window system, and the maintenance of the blind is not easy because the shade or the blind is installed inside the hollow floor.

In addition, Prior Art 1 requires that a separate motorized device be introduced to ideally operate the sunshade or blinds for the season, and when the sunshade or blinds are operated manually without a powertrain, It can be operated irrationally in terms of energy and comfort.

Another prior art for solving this problem is "Window system" (prior art 2) of Korean Registered Patent No. 10-1518835 (May 2015.05.04). Prior Art 2 is a window frame, An outer window which is fixed to the window frame and is spaced apart from the inner window to form a hollow layer, a circulation hole which is formed between the outer window and the window frame to form a flow path for circulating air in the hollow layer, And an opening / closing frame which is provided in the circulation port and opens and closes the air supply mechanism and the air exhaust port.

However, according to the prior art 2 described above, the circulation port is always opened or the circulation port is opened / closed through the cover having the detachable structure. However, since the air supply port of the circulation port is directed outdoors, It is practically impossible to install the cover in a high-rise building such as a building.

KR 10-1010203 B (2011.01.17) KR 10-1518835 B (2015.05.04)

SUMMARY OF THE INVENTION The present invention provides a window system for easily opening and closing a circulation hole provided in a hollow space formed between an outer window and an inner window to supply or exhaust outdoor air to a room It has its purpose.

Also, it is an object of the present invention to provide a window system in which opening and closing of a circulation loop is actively performed according to temperature, thereby generating optimal comfort conditions in a room and minimizing energy waste.

According to an aspect of the present invention, there is provided an image forming apparatus including a window frame, an inner window installed on the inner side of the window frame to open and close the window frame, And an outer window that is spaced apart from the outdoor side to form a hollow layer, wherein the outdoor window has a flow path through which the outdoor air flows into the hollow layer and circulates inside the hollow layer, and the outdoor air And a flow rate control unit for controlling the flow rate of the water.

Here, the outer window has an outer vertical portion facing the outdoor side and having a supply mechanism for receiving outdoor air, and an outer horizontal portion extending horizontally toward the indoor side from the lower end of the outer vertical portion and fixed to the upper surface of the window frame And an inner horizontal part extending from the outer side vertical part of the outer case to the inner side and forming the flow path, and an inner horizontal part extending from the lower end of the inner vertical part toward the outer horizontal part and bound to the outer horizontal part, .

Preferably, the outer case and the inner case are made of different materials, and the inner case is made of a material having a lower conductivity than the outer case.

Preferably, the outer case is made of aluminum or an aluminum alloy, and the inner case is made of synthetic resin.

The inner horizontal portion may include a first inner horizontal portion and a second inner horizontal portion that are divided into two forked portions so that the outer horizontal portion may be inserted therein. At least one of the first inner horizontal portion and the second inner horizontal portion may include an outer horizontal It is preferable that the engagement protrusions are formed to be engaged with the coupling protrusions formed on the base.

Preferably, the outer case is formed with an opening portion in which a part of the outer vertical portion is bent toward the indoor side, so that the glass is fixed.

The flow rate adjusting unit is preferably installed at the outer vertical portion and the upper end of the inner vertical portion.

The flow rate control unit may include an exhaust port that is coupled to the outer vertical portion and the upper end of the inner vertical portion to cross the space between the outer vertical portion and the inner vertical portion and exhausts the outdoor air introduced into the flow path to the hollow layer And a slider formed with a fixed frame and a through hole formed alternately with the exhaust port and sliding from the fixed frame to open and close the exhaust port.

Preferably, the fixed frame is formed with a guide for guiding the sliding movement by wrapping both ends of the slider.

Preferably, the detent portion is formed to allow the user to recognize opening and closing of the exhaust port when the user operates the slider by touching the fixed frame and the slider.

The detent portion may include a depression formed in the periphery of the vent hole formed in the fixed frame, and a protrusion formed in the slider corresponding to the depression.

In addition, it is preferable that the depth of the depression decreases as the depression approaches the exhaust port.

The flow rate adjusting unit may further include a thermostat provided between the slider and the outer window for operating the slider according to a temperature change to open and close the air outlet.

The thermostat includes a wax chamber which is fixed to the outer window and is filled with wax, a piston which receives a base end in the wax chamber and whose tip is fixed to the slider to adjust the displacement of the slider as the wax expands, And a guide cap integrated with the wax chamber and guiding the movement of the piston due to the expansion of the wax.

It is preferable that the inner window is provided with a double-layered glass.

The inner window preferably includes a first glass disposed on the outdoor side and a second glass separated from the first glass on the room side by a low-E coating (Low Emissivity coating).

Preferably, the outer window is one of a tinted glass or a transmittance control glass.

According to the window system of the present invention, a flow path for circulating outdoor air through a hollow layer formed between an outer window and an inner window is formed, and a flow rate control unit for controlling the flow rate of outdoor air is installed on the flow path, It is possible to control the flow rate of the outdoor air flowing into the hollow layer according to the temperature, thereby minimizing the loss of heat energy due to the cooling and heating of the room.

In addition, the flow rate control unit actively adjusts the flow rate of the outdoor air according to the outdoor temperature change, so that it is unnecessary to adjust the flow rate of the outdoor air by the user.

In addition, the outer case and the inner case, which constitute the outer window, are made of different materials to prevent thermal conduction between the outer case and the inner case, thereby minimizing the loss of heat energy due to the cooling and heating of the room.

According to the present invention, when the outer case and the inner case are made of different materials, it is easy to assemble the outer case and the inner case so as to improve the productivity of the product as well as the rigid structure, thereby improving the quality.

1 is a perspective view showing a window system according to the present invention.
2 is an exploded perspective view showing a window system according to the present invention.
3 is a sectional view showing a window system according to the present invention.
4 is an exploded perspective view showing an outer window and a flow rate control unit of the window system according to the present invention.
5 is a plan view showing a detent part of a window system according to the present invention.
6 is a perspective view showing another embodiment of the window system according to the present invention.
7 is a cross-sectional view showing the operating state of Fig.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

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

FIG. 1 is a perspective view showing a window system according to the present invention, FIG. 2 is an exploded perspective view showing a window system according to the present invention, and FIG. 3 is a sectional view showing a window system according to the present invention.

The window system according to the present invention includes a window frame 100, an inner window 200 installed on the indoor side of the window frame 100, an inner window 200 fixed to the window frame 100, And an outer window 300 spaced apart from the outdoor side to form the hollow layer 400. [

Particularly, in the window system according to the present invention, the outdoor air flows into the hollow layer 400, the flow passage 302 circulating inside the hollow layer 400 is formed in the outer window 300, A flow rate control unit 500 for controlling the flow rate of outdoor air flowing into the indoor space 400 is installed to prevent the temperature of the inner window 200 from rising by ventilating the hollow layer 400 during the summer season, It is possible to prevent the temperature of the inner window 200 from being lowered, thereby minimizing the heat energy loss in the room.

The window frame 100 is directly fixed to the structure of the building and fixed to the structure so as to support the inner window 200 and the outer window 300 installed in the window frame 100. [ The window frame 100 may be made of a metal such as aluminum or an aluminum alloy or a synthetic resin such as PVC or the like so as to prevent heat exchange between indoor and outdoor through the window frame 100, An insulating foam such as a Nisf foam can be filled.

Further, the inner window 200 is provided on the indoor side of the window frame 100 to block the inflow of the solar radiation, and comprises a double-layered glass and a frame for fixing the double-layered glass. At this time, the double-layered glass is divided into a first glass 201 having a thickness of 24 mm and a second glass 202 separated from the first glass 201 by a low-E coating (Low Emissivity coating) Lt; / RTI >

The second glass layer coated with the second glass is excellent in heat insulating performance and can be used for securing the heat insulation performance in the winter room and generated in the hollow layer 400 formed between the inner and outer windows 200 and 300 Is prevented from flowing into the indoor side.

The inner window 200 having such a structure is provided with a pivoting member (not shown) such as a hinge to one side of the inner window 200 so that the inner window 200 can be rotated from the window frame 100 toward the room, A step is formed on the window frame 100 so as to face the one side of the inner window 200 and the inner window 200 and the window frame 100 are closely contacted to support the closed state of the inner window 200. [

When the damper 110 is installed at the edge of the window frame 100 and the inner window 200 is brought into close contact with the edge of the window frame 100, the space between the inner window 200 and the window frame 100 is sealed And simultaneously the inner window 200 is rotated to absorb the impact generated when the inner window 200 is brought into close contact with the edge of the window frame 100.

The outer window 300 is spaced apart from the inner window 200 and installed in the window frame 100. A hollow layer 400 is formed between the outer window 300 and the inner window 200 at this time. In addition, the outer window 300 is provided with a third glass 301 made of transparent glass having a thickness of 7 mm and a high water absorption rate.

The third glass 301 may be made of a transparent glass as described above, but may be provided with a tinted glass having a blue or green color in order to enhance the solar radiation blocking effect. In some cases, the third glass 301 provided in the outer window 300 may have a transmittance control glass.

On the other hand, when the third glass (301) provided in the outer window (300) is made of blue or green, the ultraviolet ray blocking effect is relatively higher than those of different colors of blue and green, It has the effect of relieving tension.

Accordingly, by using the colored glass having blue or green color in the outer window 300 with the third glass 301, it is possible to reduce the eye fatigue for the user located in the room, to achieve psychological stability, and to protect from ultraviolet rays.

The outer window 300 having the third glass 301 is introduced into the hollow layer 400 formed between the inner window 200 and the outer window 300 so that the inside of the hollow layer 400 A flow path control unit 500 is installed on the flow path 302 so that the flow rate of the outdoor air flowing into the hollow layer 400 can be adjusted.

The outer window 300 is composed of an outer case 310 and an inner case 320, which will be described with reference to FIG.

4 is an exploded perspective view showing an outer window and a flow rate control unit of the window system according to the present invention. The outer case 310 includes an outer vertical portion 311 formed with a power supply mechanism 311a to which outdoor air flows and a lower portion of the outer vertical portion 311 toward the indoor side And an outer horizontal portion 312 extending horizontally and fixed to the upper surface of the window frame 100.

The inner case 320 is separated from the outer vertical portion 311 of the outer case 310 by an inner vertical portion 321 forming the flow path 302 and a horizontal outer horizontal portion 321 extending from the lower end of the inner vertical portion 321, The outer case 310 and the inner case 320 are assembled with the outer case 312 and the inner case 322 extending toward the outer case 312 and coupled to the outer case 312. Thus, The outdoor air flows into the flow path 302 through the air supply mechanism 311a formed on the outer vertical portion 311 of the outer case 310. [

The air supply mechanism 311a formed on the outer side vertical portion 311 of the outer case 310 may be formed along the longitudinal direction of the outer side vertical portion 311 as described above. 4, the feed mechanisms 311a may be formed at regular intervals in the longitudinal direction of the outer vertical portion 311, but in some cases, the feed mechanisms 311a are arranged in a plurality of rows and columns Or may be formed in the longitudinal direction of the outer vertical portion 311. In addition, the air supply mechanism 311a may be provided with a filter member (not shown) such as an insect-proofing net for blocking foreign matter from entering from outside.

The outer case 310 is formed with a notch portion 313 in which a part of the outer vertical portion 311 is bent towards the interior side. And a third glass 301 is positioned and fixed on the upper surface thereof.

At this time, when a part of the upper end of the outer vertical part 311 is bent toward the indoor side, the inner side part 313 is formed by the thickness of the third glass 301 so that the outer vertical part 311 is separated from the third glass 301 So that the load of the third glass 301 is supported by the outer vertical portion 311 to firmly support the third glass 301.

When a part of the upper end of the outer vertical part 311 is bent to form the inner tooth part 313 as described above, ribs for reinforcing the bent part on the inner side of the outer vertical part 311 are formed.

The ribs formed on the inner surface of the outer vertical portion 311 extend along the longitudinal direction of the outer vertical portion 311. The ribs are formed on the inner surface of the inner surface of the inner rib 313, And a second rib 340 formed on an inner surface of the outer vertical portion 311.

When the first ribs 330 and the second ribs 340 are formed on the inner side surfaces of the inner and outer vertical portions 311 and 311 as described above, And is formed in a circular shape that tightly surrounds the outer diameter of the bolt so as to be fixed to the frame forming the side surface of the outer window 300.

The outer case 312 is coupled to the inner case 322 of the inner case 320 to form an integral body. The outer case 310 and the inner case 320 are easily coupled The inner horizontal portion 322 of the inner case 320 is divided into a first inner horizontal portion 322a and a second inner horizontal portion 322b that are divided into two for insertion of the outer horizontal portion 312, ).

At this time, at least one of the first inner horizontal portion 322a and the second inner horizontal portion 322b is formed with a latching protrusion 322c which is coupled to the coupling protrusion 312a formed on the outer horizontal portion 312. The coupling protrusions 312a formed on the outer horizontal portion 312 and the locking protrusions 322c formed on the first inner horizontal portion 322a or the second inner horizontal portion 322b are shaped like hooks, When the horizontal portion 312 is smoothly inserted into the inner horizontal portion 322 while the outer horizontal portion 312 is detached from the inner horizontal portion 322, the coupling projections 312a and the engagement protrusions 322c are engaged It is suppressed so as not to be separated.

The inner case 320 has a rib formed at a bent portion where the inner horizontal portion 322 and the inner vertical portion 321 are connected to reinforce the strength of the inner case 320. That is, the rib formed in the inner case 320 includes a third rib 350 formed on the inner side of the inner horizontal portion 322 and a fourth rib 360 formed on the inner side of the inner vertical portion 321 And the third rib 350 and the fourth rib 360 extend along the longitudinal direction of the inner case 320.

When the third rib 350 and the fourth rib 360 are formed on the inner surface of the inner horizontal portion 322 and the inner surface of the inner vertical portion 321, 300 formed on the side surface of the bolt to be fixed to the frame.

The outer case 310 and the inner case 310 form the flow path 302 so that outdoor air can be introduced into the hollow layer 400 through the air supply mechanism 311a formed in the outer vertical part 311, 320 are made of different materials to minimize the transfer of heat between the outer case 310 and the inner case 320.

The outer case 320 is made of a material having a lower conductivity than the outer case 310. The outer case 310 is preferably made of aluminum or an aluminum alloy and the inner case 320 is made of synthetic resin.

When the outer case 310 is made of aluminum or aluminum alloy, the third glass 301 can be firmly supported. On the other hand, when the inner case 320 is made of synthetic resin, So that the temperature of the inner case 320 is prevented from being increased.

As described above, if the inner case 320 is made of a material having a low conductivity, even if the temperature of the outer case 310 rises due to sunlight during the summer season, the inner case 320 made of synthetic resin can heat the window frame 100 So that the temperature of the hollow layer 400 and the window frame 100 is prevented from rising.

When the outer case 310 and the inner case 320 are made of different materials and the inner case 320 is made of a material having a lower conductivity than the outer case 310 as described above, It is possible to prevent the heat of the window frame 100 from being transmitted to the outer case 310 by the inner case 320 even though the temperature is lower than the indoor temperature, The power consumption for cooling and heating of the refrigerator can be reduced.

A flow rate control unit 500 for controlling the flow rate of outdoor air flowing into the hollow layer 400 is installed on the flow path 302 formed by assembling the outer case 310 and the inner case 320, do.

4, the flow control unit 500 includes an outer vertical portion 311 of the outer case 310 and an inner vertical portion 321 of the inner case 320, And the inner window 200. The air flow rate of the outdoor air flowing into the hollow layer 400 formed between the inner window 200 and the inner window 200 is controlled.

The flow rate control unit 500 includes a fixed frame 510 and a slider 520. The fixed frame 510 is coupled to the upper ends of the outer vertical portion 311 and the inner vertical portion 321, 311 and the inner vertical portion 321. [0156]

At this time, a fixture such as a hook is formed on the bottom surface of the fixed frame 510 for binding with the upper ends of the fixed frame 510, the outer vertical portion 311 and the inner vertical portion 321. Bonding holes corresponding to the fixing members are formed at the upper ends of the outer vertical portion 311 and the inner vertical portion 321 to fix the fixing frame 510 to the outer vertical portion 311, And the inner side vertical portion 321. [0051]

The fixed frame 510 has an exhaust port 511 for exhausting the outdoor air introduced into the flow path 302 to the hollow layer 400. At this time, a plurality of exhaust ports 511 are formed at regular intervals along the longitudinal direction of the fixed frame 510.

The slider 520 is formed with a through hole 521 and an exhaust port 511 formed in the fixed frame 510. The slider 520 is slid from the fixed frame 510 and overlapped or staggered with the exhaust port 511 of the fixed frame 510 The position of the through hole 521 is adjusted to control the opening and closing of the exhaust port 511.

A guide 522 for guiding sliding of the slider 520 is formed on both sides of the slider 520 so that the slider 520 can be stably slid from the fixed frame 510. When the guide 522 is formed in the fixed frame 510, the slider 520 slides along the longitudinal direction of the fixed frame 510 and stably moves the slider 520 without lifting when opening and closing the exhaust port 511. [ .

When the slider 520 slides on the fixed frame 510 and opens and closes the exhaust port 511 as described above, the detent portion 530 is opened to allow the user to recognize the degree of opening / closing of the exhaust port 511 by touching And is provided on the fixed frame 510 and the slider 520. The detent portion 530 will be described with reference to FIG.

5 is a plan view showing a detent part of a window system according to the present invention. The detent portion 530 includes a depression 531 formed in the periphery of the exhaust port 511 formed in the fixed frame 510 and a protrusion 532 formed in the slider in correspondence with the depression 531. [ .

When the slider 520 is mounted on the stationary frame 510 and the slider 520 is mounted on the stationary frame 510, The protrusion 532 of the slider 520 is placed on or separated from the depression 531 of the fixed frame 510 by sliding along the longitudinal direction so that the height of the slider 520 is fixed to the fixed frame 510 The degree of opening / closing of the exhaust port 511 can be easily adjusted by the user because the user perceives the opening / closing degree of the exhaust port 511 as tactile.

The depents 531 and the protrusions 532 may be formed on the fixed frame 510 and the slider 520 respectively as described above. In some cases, the depressions 531 and the protrusions 532 may be formed on the slider 520, The protrusions 532 may be formed in the slider 520 and the protrusions 532 may be formed in the slider 520.

The depressed portion 531 of the detent portion 530 may allow the user to adjust the opening and closing degree of the exhaust port 511 by friction as the slider 520 slides in the longitudinal direction of the fixed frame 510, You might be able to recognize it. 5, the depressed portion 531 is formed to have a structure in which the depth of the depressed portion 531 decreases toward the exhaust port 511. [

As the slider 520 slides along the longitudinal direction of the fixed frame 510, the protrusions 532 are formed in the lower surface of the fixed frame 510 as the depth of the depressed portion 531 decreases toward the exhaust port 511. [ The friction between the protrusions 532 and the depressions 531 increases as the protrusions 532 move toward the exhaust port 511 at this time as the protrusions 532 move in the longitudinal direction of the fixed frame 510 within the depressions 531 The user can control the opening / closing degree of the exhaust port 511 easily by recognizing the movement of the slider 520.

Meanwhile, as described above, the window system according to the present invention can directly control the opening and closing of the slider 520, but in some cases, the slider 520 may actively operate according to the outdoor temperature. This will be described with reference to FIGS. 6 and 7. FIG.

FIG. 6 is a perspective view showing another embodiment of the window system according to the present invention, and FIG. 7 is a sectional view showing the operating state of FIG. Referring to the drawings, the flow rate control unit 500 is provided with a thermostat 540 so that the slider 520 can actively operate according to the outdoor temperature.

That is, in the flow rate control unit 500, the thermostat 540 is installed between the slider 520 and the outer window 300 to operate the slider 520 according to the temperature change to open and close the air outlet 511, The thermostat 540 comprises a wax chamber 541, a piston 542, and a guide cap 543.

In other words, the wax chamber 541 is fixed to the outer window 300 and the wax is filled. The piston 542 receives the base end in the wax chamber 541 and its tip is fixed to the slider 520 to adjust the displacement of the slider 520 as the wax expands. The guide cap 543 is integrated with the wax chamber 541 to guide the movement of the piston 542 due to the expansion of the wax.

The slider 520 is formed with a lug 523 to which the piston 542 is fixed so that the tip of the piston 542 is engaged with the lug 523 formed on the slider 520 ) And a bolt.

The wax chamber 541 may be fixed to the outer window 300 as described above. However, as shown in FIG. 6, the wax chamber 541 may be fixed to the fixed frame 510 outside the end of the slider 520, The piston 542 moves in the longitudinal direction of the fixed frame 510 to actuate the slider 520 so that the degree of opening and closing of the air outlet 511 formed in the fixed frame 510 is actively controlled .

The wax of the thermostat 540 expands in the summer so that the piston 542 is drawn out from the wax chamber 541 and the through hole 521 formed in the slider 520 and the exhaust hole 521 formed in the fixed frame 510 The outdoor air is introduced into the hollow layer 400 through the air outlet 302 formed in the outer window 300 and circulated through the air outlet 511 so that the temperature inside the hollow layer 400 is lowered Thereby minimizing the loss of heat energy for cooling the room.

The wax of the thermostat 540 is contracted during the winter season and the piston 542 is drawn into the wax chamber 541 to form the through hole 521 formed in the slider 520 and the through hole 521 formed in the fixed frame 510 The air outlets 511 are staggered so that the exhaust port 511 is closed so that the outdoor air is prevented from flowing into the hollow layer 400. As a result, the temperature inside the hollow layer 400 is maintained, Thereby minimizing the loss of power.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

100: window frame 110: damper
200: Inner window 201: First glass
202: second glass 300: outer window
301: Third glass 302: Euro
310: Outside case 311: Outside vertical part
311a: feed mechanism 312: outer horizontal part
312a: a coupling protrusion 313:
320: Inner case 321: Inner vertical part
322: inner horizontal part 322a: first inner horizontal part
322b: second inner horizontal part 322c:
330: first rib 340: second rib
350: Third rib 360: Fourth rib
400: hollow layer 500: flow rate control unit
510: stationary frame 511: exhaust port
520: Slider 521: Through hole
522: guide 523: rug
530: Detent portion 531: Depression portion
532: projection 540: thermostat
541: Wax chamber 542: Piston
543: Guide cap

Claims (9)

Window frames;
An inner window installed on the indoor side in the window frame and openable and closable from the window frame; And
And an outer window fixed to the window frame and spaced apart from the inner window to form a hollow layer,
The outer window
An outdoor air flows into the hollow layer and circulates inside the hollow layer;
On the flow path
And a flow control unit for controlling a flow rate of outdoor air flowing into the hollow layer,
The outer window
An outer case having an outer vertical portion formed with an air supply mechanism for receiving outdoor air toward the outdoor side and an outer horizontal portion extending horizontally toward the indoor side from the lower end of the outer vertical portion and fixed to the upper surface of the window frame; And
And an inner horizontal portion extending from the outer vertical portion of the outer case to the inner side and forming the flow path, and an inner horizontal portion extending toward the outer horizontal portion from the lower end of the inner vertical portion and bound to the outer horizontal portion. Lt; / RTI >
The inner horizontal portion
And a first inner horizontal part and a second inner horizontal part that are divided into two fork so that the outer horizontal part is inserted,
At least one of the first inner horizontal portion and the second inner horizontal portion is formed with a latching jaw which is engaged with a coupling protrusion formed on the outer horizontal portion,
The flow rate control unit
And an outer vertical portion and an upper vertical inner portion,
The flow rate control unit
A stationary frame coupled to the outer vertical part and the upper end of the inner vertical part, the stationary frame crossing between the outer vertical part and the inner vertical part and having an exhaust port for exhausting the outdoor air introduced into the flow path to the hollow layer; And
And a slider which is formed with through-holes alternating with the exhaust port and slides from the fixed frame to open and close the exhaust port,
The out-
And a glass portion is fixed by forming a portion of the outer vertical portion bent toward the indoor side,
The fixed frame
A guide for guiding sliding of both ends of the slider is formed,
Wherein the outer case and the inner case are made of different materials, and the inner case is made of a material having a lower conductivity than the outer case,
The fixed frame and the slider
A detent portion is formed so that when the user operates the slider, the opening and closing of the exhaust port can be recognized as tactile,
The detent portion
A depression formed in the periphery of an exhaust port formed in the fixed frame; And
And a protrusion formed on the slider corresponding to the depression,
The flow rate control unit
And a thermostat provided between the slider and the outer window to operate the slider according to a temperature change to open and close the exhaust port,
The thermostat
A wax chamber fixed to the outer window and filled with wax;
A piston accommodating a base end in the wax chamber and having a tip fixed to the slider to adjust the displacement of the slider as the wax expands; And
And a guide cap integrally joined to the wax chamber and guiding the movement of the piston due to the expansion of the wax,
Wherein the outer vertical portion and the bent portion of the seat portion are formed with ribs extending along the longitudinal direction of the outer vertical portion on the inner side surface thereof,
The rib
A first rib formed on an inner surface of the seat portion; And
And a second rib formed on an inner surface of the outer vertical portion,
The first and second ribs
Wherein the outer vertical portion is formed in a circular shape to surround the outer diameter of the bolt so as to be fixed to the frame forming the side of the outer window,
The inner window is provided with a first glass provided on the outdoor side and a second glass separated from the first glass by a low-E coating (Low Emissivity coating)
The outer window may be provided with a third glass made of either tinted glass or a transmittance adjusting glass
The inner window
A tilt is formed on the window frame so as to face the one side of the inner window provided with the tiltable member so that the tiltable member is rotatable from the window frame toward the room, So as to support the closed state of the inner window,
A damper is installed at a step of the window frame to hermetically close the inner window and the window frame when the inner window is brought into close contact with the edge of the window frame and at the same time the inner window is rotated to close the window frame And absorbs the impact generated when the door is opened. delete delete delete delete delete delete delete delete

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