KR20200086775A - Ventilation system of indoor - Google Patents

Abstract

The present invention relates to an indoor ventilation system, which can ventilate indoor air without opening a window. The indoor ventilation system of the present invention inserts and installs a second shield gasket between a fixed frame and an operating part, thereby coupling the operating part to the fixed frame to secure airtight performance when the window is closed and having a wide contact area so that airtight force can be improved while a wing part of the second shield gasket is compressed by a flange of the operating part. Also, the indoor ventilation system allows elasticity to be maintained by restoring force of the wing part even when being used for a long period so that the airtight performance can be maintained.

Description

Indoor ventilation system {VENTILATION SYSTEM OF INDOOR}

The present invention relates to an indoor ventilation system, and more particularly, to an indoor ventilation system that allows ventilation of indoor air without opening a glass window.

Windows are an important part of the building. The function of the window is basically for natural light and natural ventilation. Not only does it look good, it also requires watertightness, sound insulation and protection.

The window opening and closing method includes a slide method and a casement method. The slide method forms at least a double rail on the frame of the window frame, and a plurality of windows are alternately coupled to the double rail. In addition, an insect repellent window is installed outside the open window.

The casement-type window is configured to divide the window frame frame into a plurality of areas, and an area that does not need to be opened and closed is fixed to the window frame frame directly, and a casement-type window is installed in any one of the areas.

1 is a view schematically showing a conventional window.

Referring to Figure 1, a conventional window frame includes a window frame (2) of a rectangular shape, and a pair of windows (4) sliding along the rails formed on the upper and lower parts of the window frame (2). The window 4 includes a window frame 4a and glass 4b mounted to the window frame 4a. When the window 4 is moved for ventilation or the like, one side of the window frame 2 is opened, and external air is introduced through the open space.

These conventional windows and doors are provided with a window frame (4a) and a frame (2) supporting the glass (4b), the window frame (4a) and the frame (2) is a factor that decreases the heat insulation, air tightness, watertight performance as the circumferential length is longer However, if the size of the open space is too large to act as a safety rail, it threatens the safety of the risk of intrusion by outsiders and the fall of residents.

In addition, the window frame (4a) and the frame (2) is a factor that visually blocks the outside view of the occupant.

The window that can be opened and closed as described above, the window frame and the window frame must be installed in a dual configuration, and the window frame must include an insulating, waterproof, and soundproof structure when combined with the window frame as well as the window opening and closing structure. Therefore, a window that can be opened and closed is more expensive than a window that cannot be opened and closed.

In addition, the openable windows as described above, since the off area is opened as it is, the externally contaminated air may be introduced into the room as it is. This makes me afraid to open the window.

Although ventilation is essential in the building, windows cannot be opened on days when external air pollution is severe. This can increase the pollution of indoor air, which can harm health.

In addition, since indoor cleaning often occurs because the window is closed due to fear of opening the window, the indoor air pollution degree is increased.

Domestic Registration Utility Model Publication No. 20-0331996

An object of the present invention for solving the problems of the prior art as described above is to form an opening in the windowpane, install a fixed frame in the opening, close the window or open the window by coupling or separating the operation portion to the fixed frame. In an indoor ventilation system, a shield gasket capable of improving sealing performance between a fixed frame and an operation part is inserted, and a coupling structure is provided.

In order to achieve the above object, the indoor ventilation system according to the present invention,

Provided is an indoor ventilation system having an opening formed by drilling a hole in a window glass, an annular fixing frame inserted into the opening, and an operation unit capable of opening and closing the fixing frame.

In the above indoor ventilation system, there must be a sealing means between the fixed frame and the operation unit. That is, when the operation portion is coupled to the fixed frame, air must be blocked so as not to pass between indoor and outdoor.

When a shield gasket, such as a simple O-ring, is applied between the fixed frame and the operating part, there is a disadvantage that a contact area is small and sealing performance may be deteriorated when used for a long time.

In the present invention, to improve the above problem, in order to seal between the fixed frame and the operating portion, a second shield gasket is inserted and installed between the fixed frame and the operating portion.

A second gutter for inserting a shield gasket is formed on the outer flange of the fixed frame, and a second shield gasket is inserted into the second gutter and sealed between the fixed frame and the operation part.

The second shield gasket,

It includes a body portion inserted into the second gutter, and a wing portion protruding outwardly from the body portion.

The second shield gasket,

A plurality of protrusions are further formed around the body portion, and are installed by being pressed against the sidewalls of the second gutter.

In order to couple the operation portion to the fixed frame and press the second shield gasket in close contact, coupling means for coupling and fixing the operation portion to the fixed frame is required.

In the fixing frame, an inner flange corresponding to the outer flange is further formed, and a plurality of insertion grooves are formed in the inner flange, and the outer circumferential surface of the cylindrical portion of the operation portion passes through the insertion groove, and is rotated to the inner flange by rotation of the operation portion. A plurality of engaging portions are further formed, and the flange of the operation portion is in close contact with the second shield gasket by sealing the coupling portion by inserting the operation portion into the fixing frame to rotate, thereby sealing the fixed frame and the operation portion. Is done.

The indoor ventilation system according to the present invention can reduce the cost of a window installation because there is no need for a conventional window frame and frame for supporting and moving a conventional glass plate. Since it can be installed airtight on the outer wall, there is an effect of improving the heat insulation, airtightness and water tightness.

In addition, the present invention, by inserting and installing the second shield gasket between the fixed frame and the operation portion, it is possible to secure the sealing performance when the window is closed by coupling the operation portion to the fixed frame.

In addition, according to the present invention, when the operating portion is inserted into the fixed frame and fixed through the coupling portion, the wing portion of the second shield gasket is compressed by the flange of the operating portion, thereby increasing the sealing area and improving the sealing force. The elasticity is maintained to maintain the sealing performance.

1 is a view schematically showing a conventional window.
2 schematically shows an indoor ventilation system according to a preferred embodiment of the present invention.
3 is an exploded view schematically showing an exploded structure of an indoor ventilation system according to a preferred embodiment of the present invention.
Figure 4 is an exploded perspective view showing the configuration of the fixed frame and the operating portion of the indoor ventilation system according to a preferred embodiment of the present invention.
Figure 5 is a perspective view of the disassembled the operating portion in the fixed frame of the indoor ventilation system according to a preferred embodiment of the present invention.
Figure 6 is a cross-sectional view of a state combined with a fixed frame and the operating portion of the indoor ventilation system according to a preferred embodiment of the present invention.
7 is an explanatory view of an operation part mounting structure of an indoor ventilation system according to a preferred embodiment of the present invention.
8 is an exemplary front view of the first shield gasket before installation.
9 is a schematic perspective view of a first shield gasket installed.
Figure 10 is a schematic cross-sectional view showing a first shield gasket installation process between the fixed frame and the glass opening of the present invention.
11 is a schematic cross-sectional view showing a first shield gasket installation state between the fixed frame and the glass opening of the present invention.
12 is an exemplary cross-sectional view of an indoor ventilation system according to an embodiment of the present invention.
13 is an explanatory view of a second shield gasket of an indoor ventilation system according to an embodiment of the present invention.
14 is an explanatory view of a combined structure of a fixed frame and an operation part of an indoor ventilation system according to an embodiment of the present invention.
15 is a cross-sectional view schematically showing the structure of an indoor ventilation system having an outer cover shield gasket according to another embodiment of the present invention.
16 is a front schematic configuration diagram of the outer cover shield gasket of the present invention.
17 is a schematic perspective view showing a partially cut section of the outer cover shield gasket of the present invention.
18 is a schematic illustration of the structure of the elastic portion of the outer cover shield gasket according to another embodiment of the present invention.
19 is a schematic cross-sectional view showing the configuration of an indoor ventilation system having a fixed spacer-integrated frame structure according to the present invention.

The present invention will be described in more detail with reference to the following examples. It should be understood that the specific embodiments described herein are used to describe the present disclosure and are not intended to limit the present disclosure.

The configuration of the present disclosure, although numbered, is not limited to the same shape, but includes a configuration that achieves functionality. In addition, the steps of the present invention are not used to limit the order, and the relative order of steps may be adjusted unless the order of steps is explicitly specified, or step execution does not require additional steps as a basis. The interior and exterior described herein are indoor and outdoor.

Hereinafter, an indoor ventilation system according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

2 is a view schematically showing an indoor ventilation system according to a preferred embodiment of the present invention.

2, the indoor ventilation system according to a preferred embodiment of the present invention,

A hole is formed in the window glass 100 to form an opening 110, and a ventilation window is installed to open and close the opening 110. The present invention, which forms an opening and installs a ventilation window, may be installed only in one window, or may be installed in a plurality. Multiple can be installed. When forming the opening, the position, number, size and shape should be designed in consideration of the safety factor of the glass. The shape should preferably be free of corners, such as round or oval.

The ventilation window may be configured as a plug type that can be inserted into or removed from the opening 110. In addition, the ventilation window may be a configuration in which a fixed frame is inserted into the opening 110 to fix it, and a stopper type, a slide type, or a rotating type operation part or a door is installed on the fixed frame to open or close.

The ventilation window may be composed of a single component or may be divided into a plurality of components. When configured as one component, the inner periphery of the opening 110 is sealed with a shield gasket, and is configured to insert or remove a stopper made of one component in close contact with the shield gasket. Insert or remove the stopper to open or close the window.

However, the structure in which the stopper and the shield gasket are tightly considered in consideration of the sealing function may cause damage to the shield gasket, and the structure that is loosely fitted may deteriorate the sealing function.

Accordingly, in a preferred embodiment of the present invention, a ventilation window structure composed of a plurality of parts is proposed.

3 is an exploded view schematically showing an exploded structure of an indoor ventilation system according to a preferred embodiment of the present invention. As shown in Figure 3,

The opening 110 formed in the window pane 100, the fixed frame 200 sealed and fixed to the inner periphery of the opening 110 and the inside and outside are opened, and coupled to the fixed frame 200 to block or open the opening It includes an operation unit 300.

A first shield gasket 120 is inserted between the opening 110 and the fixed frame 200 to be sealed. An air filter 400 may be installed at an outer end portion inside the fixed frame 200. A second shield gasket 210 is inserted between the fixed frame 200 and the operation part 300. A cover 310 may be further coupled to the indoor side of the operation unit 300.

The operation unit 300 may be any component that is provided with a closed cross-section to block or open a through opening of the fixed frame 200. As an example, the fixing frame 200 may be inserted or removed, and one end may be formed of a blocked member. As another example, the indoor cover of the fixed frame 200, a casement or a sliding door may also be configured. In the embodiment with reference to the drawings of the present invention, a configuration capable of inserting or removing the operation unit 300 into the fixed frame 200 will be described.

The window glass 100, the glass plate may be composed of a single sheet, may be composed of a double or triple glass plate for thermal insulation. When the opening 110 is formed in the double or triple glass plate, a spacer is inserted between the glass plate and the glass plate, and a shield adhesive is interposed and sealed.

For the sealing structure between the fixed frame 200 and the opening 110, a packing material, an adhesive material, or the like is used. If a thin adhesive is simply applied and fixed, the adhesive site may be damaged by deformation or expansion or contraction due to temperature change, or wind or shock applied to the glass plate, thereby creating a gap.

In view of the above problems, the present invention uses a first shield gasket 120 having an elastic force capable of absorbing fine displacement. The first shield gasket 120 is pre-molded with a shield material such as silicon, and is attached to the inner periphery of the opening 110.

2 schematically shows an indoor ventilation system according to a preferred embodiment of the present invention.

3 is an exploded view schematically showing an exploded structure of an indoor ventilation system according to a preferred embodiment of the present invention.

Figure 4 is an exploded perspective view showing the configuration of the fixed frame and the operating portion of the indoor ventilation system according to a preferred embodiment of the present invention, Figure 5 is an exploded state of the operating portion in the fixed frame of the indoor ventilation system according to a preferred embodiment of the present invention 6 is a cross-sectional view of a state in which a fixed frame and an operation unit of an indoor ventilation system according to a preferred embodiment of the present invention are combined.

The configuration of the fixed frame and the operation unit will be described with reference to FIGS. 4 to 6.

The fixed frame 200 is composed of a cylindrical portion 201 opened to the inner and outer sides, and an outer flange 203 protruding from the inner peripheral edge of the cylindrical portion 201. The cylindrical portion 201 is tightly inserted into the inner periphery of the first shield gasket 120 to protrude to the outdoor side, and the flange 203 is caught by the glass plate from the indoor side.

The first shield gasket 120 is sandwiched between the flange 203 and the glass 100 and between the inner periphery of the opening 110 and the outer periphery of the cylindrical portion 201. The first shield gasket 120 is hermetically fixed by bonding to the opening 110 and the fixing frame 200 using an adhesive.

The operation unit 300 may be inserted into or removed from the fixed frame 200. The operation part 300 includes a cylindrical part 301 that is inserted into the cylindrical part 201 of the fixed frame 200, and a flange 302 protruding from the inner peripheral edge of the cylindrical part 301. , The outer surface of the cylindrical portion 301 is composed of a blocked bottom surface 305.

A second cutter 211 for inserting a shield gasket is formed on the indoor front end flange of the fixed frame 200, and a second shield gasket 210 is inserted into the second cutter 211. When the second shield gasket 210 is fixed by inserting the operation unit 300 into the fixing frame 200, the second shield gasket 210 is in close contact with the flange 302 of the operation unit 300, thereby fixing the frame 200 and the operation unit 300. Seal the gap.

As a structure for coupling the operation unit 300 to the fixed frame 200, there are a screw coupling structure and a slide structure. The inner wall of the cylindrical portion 201 of the fixed frame 200 and the outer wall of the cylindrical portion 301 of the operation portion 300 may be screwed together by forming threaded portions corresponding to each other. In addition, the inner wall of the cylindrical portion 201 of the fixed frame and the outer wall of the cylindrical portion of the operation unit 300 may be configured to have a structure that can be pushed in and out without any structure.

In a structure that can be simply inserted and taken out rather than a screwed connection method, a fixed coupling portion capable of sealing the second shield gasket 210 while pressing is required. That is, it is necessary to insert the operation unit 300 into the fixed frame 200 and to be fixed.

In an embodiment of the present invention, the inner flange 303 is formed on the indoor front end of the fixed frame 200, and a plurality of fitting hole insertion grooves 203a are formed on the inner flange 303. The operation portion 300 passes through the insertion groove 203a on the outer wall of the cylindrical portion 301 and rotates the operation portion 300 so that the engaging portion 303 caught on the inner flange 303 protrudes. . The insertion groove 203a and the coupling portion 303 correspond to each other, and it is preferable to constitute at least one pair. They are combined in pairs at positions corresponding to each other to balance.

The fixed frame 200 is installed to protrude toward the outdoor side of the opening 110. A first garter 221 is formed on the outer circumferential surface of the protruding fixed frame 200. The first garter 221 is a groove of a phantom, allowing rainwater to gather and flow down. Rainwater quickly flows through the first locker 221 of the fixed frame 200, and watertightness is ensured by the first shield gasket 120.

On the other hand, since the operation part 300 is fitted and fixed to the fixed frame 200, the inflow of rainwater may be blocked because it is sealed by the second shield gasket 210. However, even when the operation unit 300 is installed, rainwater may flow between the fixed frame 200 and the operation unit 300. In the separated state by pulling out the operation unit 300, rainwater may flow into the room as it is. The air filter 400 is installed at the inner end of the fixed frame 200, but it cannot block rainwater. Even if the rainwater does not flow into the room, the incoming rainwater may remain and mold may be formed. In winter, it is frozen and cannot remove the operation unit 300.

In the present invention, a structure for preventing the inflow of rainwater as described above is formed. A plurality of annular blocking walls 231 are formed on the inner circumferential wall of the fixed frame 200, and a plurality of annular blocking walls 331 are also formed on the outer circumferential wall of the operation unit 300.

The annular blocking wall 331 of the operation unit 300 forms a guider 332 in the longitudinal direction. The guider 332 is preferably formed to protrude slightly higher than the annular blocking wall 331 of the operation unit 300. The guide 332 prevents the phenomenon that the annular blocking wall 331 of the operating part 300 is caught by the annular blocking wall 231 of the fixed frame 200 when the operating part 300 is fitted to the fixed frame 200. do.

A plurality of guiders 332 should be formed at equal intervals, and it is preferable to form four or more. A guider is not formed in the annular blocking wall 231 of the fixed frame 200. When the guider is formed on the fixed frame 200, a clogged space in which the introduced water does not flow occurs, so that the guider is not formed on the fixed frame 200.

In order to drain when rainwater flows, a drain hole 242 is formed on the outdoor side lower surface of the fixed frame 200 to drain water to the lower side of the outdoor side.

A flow path groove 241 is formed in the annular blocking wall 231 of the fixed frame 200 so that water flows through the drain hole 242. The drain hole 242 and the flow path groove 242 are installed so that the bottom surface when the fixed frame 200 is installed. The flow path grooves 241, by dispersing projections in the center so that water flowing from both sides flows into the drain holes 241, and forming grooves on the left and right sides of the dispersion projections, thereby dispersing the water in two directions and flowing into the drain holes, Do not overflow with bottlenecks.

In particular, the inner peripheral wall of the cylindrical portion 201 of the fixed frame 200 is formed as an inclined surface 201a inclined from the indoor side to the outdoor side. The inflow water flows from the indoor side to the outdoor side by the inclined surface 201a so that it can be discharged to the outside through the drain hole.

The operation unit 300 may be configured in a hat shape. As a hat-shaped hollow structure, it becomes a cylindrical storage room structure when viewed from the inside. The article may be stored in the storage space of the operation unit 300, or the cover 310 may be attached and installed to improve the design. The cover 310 and the operation unit 300 may be combined in various forms such as bolt coupling, hook coupling, screw coupling, or may be configured by bonding with an adhesive. However, when the cover 310 is attached, it is preferable that a handle portion capable of inserting or removing the operation portion 300 into the fixed frame 200 is formed.

Using the hollow structure of the operation unit 300 and the cover 310, a small water tank, an electronic clock, a lamp, a pot plant, a wireless speaker, a piggy bank, a mirror-mounted storage box, and the like can be individually configured.

The operation unit 300 can be inserted into the fixed frame 200 to close the ventilation window and pull it out to open the ventilation window. When the operation unit 300 is pulled out, dust or foreign substances are filtered by the air filter 400 installed at the inner outer front end of the predetermined frame 200. The operation unit 300 can be taken out to ventilate, and the air filter 400 can block the inflow of dust or foreign matter.

In order to open the ventilation window, it is necessary to have a structure to pull out the operating part 300 from the fixed frame 200 and mount it. Although it may be mounted on the outside, a structure that can be mounted on the fixed frame 200 is better.

7 is an explanatory view of a structure for mounting an operation unit of an indoor ventilation system according to a preferred embodiment of the present invention.

In the present invention, the hook 351 is formed at the front end of the outer wall of the cylindrical portion 301 of the operation portion 300. The hook 351 illustrates a hook type that can be hung on the inner flange 203 of the fixing frame 200. As another example, it may be configured as a tapered suspension that fits into the insertion groove 203a. In this way, since the operation part 300 can be hung on the fixed frame 200 easily, the operation part 300 is easily removed and stored, and it is easy to find and combine it again.

In the indoor ventilation system provided by the present invention, an opening is formed in a window glass to provide an opening and closing ventilation window, and opening and closing of the ventilation window enables indoor ventilation. The small size of the openings greatly prevents the risk of falling children and improves the safety factor. In addition, the sound insulation and the insulation effect of the glass window are improved by close contact with the glass window. In addition, the cover portion can be customized to greatly improve the space utilization and beauty of the window body.

Meanwhile, an opening 110 is formed in the window pane 100, a fixed frame 200 is installed in the opening 110, and a sealing structure between the opening 110 and the fixed frame 200 is required. For sealing, the first shield gasket 120 may be used.

However, when the fixed frame 200 is installed by simply inserting it into the shield gasket, there is a fear that the fixed frame 200 is displaced to the indoor side. Accordingly, a first shield gasket is installed in a sealing structure by injecting a silicone adhesive between the fixed frame 200 and the opening 110.

When the adhesive is used in this way, when the fixing frame 200 fails, it cannot be easily taken out from the site to the interior.

Another embodiment of the present invention provides a first shield gasket structure that can be easily inserted into and fixed to the fixed frame 200 by changing the structure of the first shield gasket, and easily taken out to the indoor side.

8 is an exemplary front view of a first shield gasket of an indoor vision system according to the present invention before installation. The first shield gasket 120, referring to Figure 8,

It is made of a donut shape having a through portion 1201 formed in the center of a disk made of a good elastic material, and an attachment surface 1211 for attaching to the indoor side glass plate 110 of the opening 110, and the opening 110 It is characterized by consisting of a body portion 1212 from the inner tip of the attachment surface 1211 corresponding to the inner peripheral width of the inner edge to the inner periphery of the through portion 1201.

The inner peripheral edge of the through portion 1201 further includes an elastic portion 1213 that protrudes in the outdoor direction.

9 is an explanatory diagram of the installation process of the first shield gasket of the indoor ventilation system according to the present invention.

As described above, the first shield gasket 120 is formed in a donut shape in which a through portion 1201 is formed at the center. The attachment surface 1211 of the first shield gasket 120 is attached to the indoor windowpane 100 around the opening 110. As an attachment method, it can be attached using an adhesive 121.

With the donut-type first shield gasket 120 attached to the indoor side, the fixing frame 200 is pushed into the opening 110. The cylindrical portion 201 of the fixed frame 200 pushes the body portion 1212 of the first shield gasket 120 into the opening 110.

10 is an explanatory view of a form after the first shield gasket of the indoor ventilation system according to the present invention is installed.

When the body portion 1212 of the first shield gasket 120 is pushed by the cylindrical portion 201 of the fixed frame 200, the through portion 1201 is deformed into a cap shape as shown in FIG. Here, the diameter of the through portion 1201 is smaller than the outer diameter of the fixed frame 200 cylindrical portion 201. Therefore, when the fixed frame 200 is pushed, the diameter of the through portion 1201 increases as the body portion 1212 increases, and the cylindrical portion 201 passes through.

11 is a schematic cross-sectional view showing a state in which a first shield gasket is installed in an indoor ventilation system according to the present invention.

With the first shield gasket 120 attached to the indoor side, the fixed frame 200 is pushed. The width of the body portion 1212 of the first shield gasket 120 corresponds to the width of the opening 110. The body 1212 of the first shield gasket 120 is inserted between the inner periphery of the opening 110 and the outer periphery of the fixed frame 200 to be in close contact.

The first shield gasket 120 of the present invention further forms an elastic portion 1213 protruding from the inner periphery of the through portion 1201. The elastic portion 1213 may be sealed by tightly pressing the inner circumferential surface of the outdoor side glass plate of the opening 110 and the cylindrical portion of the fixed frame 200 with a stronger compression.

The elastic portion 1213 may be configured to have a structure folded in a round shape by inverting the inner circumferential tip of the through portion 1213. Alternatively, the elastic part 1213 may be formed of a circular/elliptical protrusion having an empty space formed therein, and as another example, the outer wall and the opening of the fixed frame 200 may be formed of a folded inclined wing structure or the like ( It may be configured to be in close contact between the inner periphery of 110) to provide elastic force. The shape or structure of the elastic portion is not limited.

In addition, in the present invention, clamping means 260 for fixing the fixing frame 200 is further included. The clamping means 260 is installed on the fixed frame 200 protruding out of the opening 110. The fixing frame 200 is fixed to prevent it from being pushed into the interior.

The clamping means 260 may be configured as a hook type that forms a hook groove in the fixing frame 200 protruding to the outside of the opening 110 and inserts it into the hook groove to fix it.

The hook-type clamping means 260 includes a hook portion 262 and a hook portion 262 protruding from the head portion 261, the head portion 261 hooked into the hook groove, and bent into the hook groove so that the tip is in contact with the glass plate. Includes a pad portion 263 attached to the front end of the) is in close contact with the glass plate. In addition, a packing 264 to prevent rainwater from penetrating into the hook groove may be further included.

In addition, the clamping means 260 is pivotably installed on the outer wall of the fixed frame 200 so as to be rotatable by a hinged hook, and after the fixed frame 200 is inserted and installed, it is rotated to rotate and rotate with the outdoor glass. It may be configured to secure the fixed frame 200 in contact. The rotatable structure can be installed or detachably installed on the cylindrical portion 201 of the fixed frame 200 so that the end of the hook having elasticity can be rotated, and can be configured in various types of structures, and such a structure is not limited. No.

As described above, the first shield gasket 120 is manufactured in a donut shape to attach an edge to the indoor glass plate. With the fixed frame 200, the central portion of the first shield gasket 120 is pushed between the openings 110 to fit. As the center of the first shield gasket 120 protrudes in a cylindrical shape, a shield gasket 120 is installed between the inner periphery of the opening 110 and the fixed frame 200.

Therefore, it can be easily inserted and installed in the field. Since the shield gasket maintains elasticity in a forcedly curved state, adhesion performance may be improved. The elastic portion 1213 may be further formed to more strongly compress the outdoor front end portion of the opening 110 to prevent rainwater from entering. In addition, since the fixed frame 200 and the first shield gasket 120 are installed in a simple fitting state, the fixed frame 200 can be easily taken out to the indoor side.

In addition, by supporting the fixed frame 200 so that an elastic force is applied to the outdoor side using the fixed frame 200 clamping means 260, the fixed frame 200 pressurizes the first shield gasket 120, thereby causing The adhesion performance is improved, and the separation of the fixed frame 200 can be prevented.

13 is an explanatory view of a second shield gasket of an indoor ventilation system according to an embodiment of the present invention.

In the present invention, the second gutter 211 is formed on the outer flange 202 of the fixed frame 200, and the second shield gasket 210 is inserted into the second gutter 211 to be installed and the flange of the operation part 300 is inserted. It is configured to be in close contact with 302 to shield. The second shield gasket 210 may have an o-ring having a circular or elliptical cross section as a second shield gasket. The O-ring has a narrow contact surface with the flange 302 of the operation unit 300, so that the shielding effect may be reduced.

Accordingly, the present invention proposes the structure of the second shield gasket 210 having the shape shown in FIG. 13.

Includes a body portion 2111 inserted into the second gutter 211 and a wing portion 2112 with one end integrally connected to the body portion 2111 and the other end opened at a predetermined angle with respect to the body portion 2111 It is configured by.

When the second shield gasket 210 configured as described above is inserted into the second gutter 211 and fixed by inserting the operation unit 300 into the fixing frame 200, the flange 302 of the operation unit 300 is The wing portion 2112 is pressed and compressed. Since the flange 302 of the operation part 300 and the wing part 2112 of the second shield gasket 210 come into close contact, the contact area is widened and the shielding effect is increased.

In addition, one or two protruding portions 2113 linearly protruding from the circumferential surface of the body portion 2111 are further formed. When the body part 2111 is inserted into the second gutter 211, the protrusion 2113 is in close contact with the sidewall of the second gutter 211. Due to this, even if the operating unit 300 is separated from the fixed frame 200, the second shield gasket 210 is not released.

Although not shown in the drawing, a line-shaped groove portion in which the protrusion 2113 is seated is formed on a sidewall of the second gutter 211, or when the body portion 2111 is pressed and pushed into the second gutter 211, the protrusion As the (2113) is compressed, it is possible to further form a locking protrusion that can ride over.

In order to maintain the shielding state between the fixed frame 200 and the operation part 300 by the second shield gasket 210, the operation part 300 is inserted into the fixed frame 200 to be fixedly coupled. Means are needed.

13 is an explanatory view of a fixed frame and an operation part of an indoor ventilation system according to an embodiment of the present invention, and FIG. 14 is an explanatory structure of a fixed frame and an operation part of an indoor ventilation system according to an embodiment of the present invention. It is.

A coupling portion 316 formed of a locking portion 316a protruding in the longitudinal direction and a pressing coupling portion 316b formed in a circumferential direction at the end of the locking portion 316a is formed on the outer periphery of the operation portion 300, , On the inner periphery of the fixed frame 200, a locking piece having a width corresponding to the length of the locking portion 316a may be formed to protrude in the circumferential direction.

When a separate engaging piece is formed on the inner periphery of the fixed frame 200, the engaging piece can be formed instead of the inner flange 203. Inserting and rotating the operation unit 300 into the fixed frame 200, the pressure coupling unit 316a is positioned on the outside of the engaging piece to be in close contact. Accordingly, the operation unit 300 may be coupled to and fixed to the fixed frame 200. It is also possible to configure the pressure coupling portion 316a or the inclined portion on the engaging piece to be tightly tightened when rotating.

In the embodiment of the present invention, as shown in Figures 13 and 14,

A plurality of insertion grooves 203a are formed in the inner flange 203 of the fixed frame 200, and a plurality of coupling portions 316 corresponding to the plurality of insertion grooves 203a are formed in the operation unit 300. And, the engaging portion 316 is inserted into the inside through the insertion groove (203a), the pressing portion 316b of the engaging portion 316 by rotating the operating portion 300, the inner flange (203) It is structured to be fitted to the outside.

In addition, an inclined portion 218a and a pressure protruding portion 218b are formed in the inner flange 203 into which the pressure coupling portion 316a is fitted. When the operation unit 300 is inserted and rotated, the pressure coupling unit 316a is interfered to be forcedly fitted, and the pressing force is applied to the operation unit 300 in the direction of the fixed frame 200.

As described above, by combining the operation unit 300 to form a coupling structure so that the pressing force acts in the direction of the fixed frame 200, the second shield gasket 210 is compressed while maintaining the shield state. In particular, since the wing portion 2112 is pressed against the second shield gasket 210, the contact area is wide, thereby improving shield performance.

A first shield gasket structure of another structure of the present invention is proposed.

15 is a cross-sectional view schematically showing the structure of an indoor ventilation system having an outer cover shield gasket according to another embodiment of the present invention, FIG. 16 is a front schematic configuration diagram of an outer cover shield gasket of the present invention, and FIG. 17 is It is a schematic perspective view showing a partial cut-away section of the outer cover shield gasket of the present invention.

The opening 110 is formed in the window pane 100, the fixed frame 200 is inserted into the opening 110, and the operation unit 300 is inserted into the fixed frame 200 to close the fixed frame 200. The ventilation window is closed and the operation unit 300 is pulled out to open the fixed frame 200 to open the ventilation window.

In another embodiment of the present invention, an outer cover shield gasket 500 is installed to block the inflow of shield and rainwater between the opening 110 and the fixed frame 200.

The outer cover shield gasket 500 is an annular structure that blocks the opening 110 from the outside (EXT), and has an annular structure having a predetermined width from the through hole 501 formed in the center and the through hole 501. A tip cover portion 502 covering the outer tip portion of the fixed frame 200 and an outer periphery of the fixed frame 200 and an inner periphery of the opening 110 formed to protrude from the outside of the tip cover portion 502. Cylindrical shield gasket portion 503 inserted between the first elastic portion 504 protruding from the outer periphery of the cylindrical shield gasket portion 503 and the tip cover portion 502 extending from the opening Including the outer cover portion 505 to cover the outer surface of the (110), and a second elastic portion 506 is formed protruding on the inner surface of the front end of the outer cover portion 505 to elastically contact the glass plate 100 It is composed.

The present invention configured as described above is the same as separating the fixed frame into two parts. The fixed frame 200 inserted from the indoor side has an annular structure and has an outer flange 202 formed on the indoor side. As the fixed frame inserted from the outdoor side, the outer cover shield gasket 500 is installed.

First, on the outdoor side, the outer cover shield gasket 500 is installed on the outdoor side of the opening 110. On the indoor side of the opening 110, the annular fixing frame 200 is fitted and installed. Two parts are fitted by fitting the outer periphery of the cylindrical portion 201 of the fixed frame 200 to the inner periphery of the cylindrical shield gasket portion 503 of the outer cover shield gasket 500. At this time, the tip of the cylindrical portion 201 of the fixed frame 200 is in close contact with the tip cover portion 502 of the outer cover shield gasket 500. A first elastic portion 504 is formed on the outer periphery of the cylindrical shield gasket portion 503 of the outer cover shield gasket 500. The first elastic portion 504 is pressurized by inserting and fixing the fixing frame 200 to close and seal the inner circumference of the opening 110. In addition, the front end portion of the outer cover portion 505 is curved with elasticity in the direction of the glass plate 100, and the second elastic portion 506 is formed. It is pressed against the second elastic portion 506 to adhere to the glass plate.

Here, although not shown in the drawing, a drain hole is further formed in the second elastic portion 506, and an outer cover shield gasket 500 is installed so that the drain hole is located on the lower surface. Accordingly, rainwater flowing between the second elastic portion 506 and the glass plate 100 from the top or side may flow down between the first elastic portion 504 and the outer cover portion 505 and be drained to the volleyball hole. In addition, the rainwater flowing through the through part 501 flows down through the drainage structure between the fixed frame 200 and the operation part 300 and is drained through the volleyball hole formed in the fixed frame 200 to form a volleyball hole in the outer frame. Can be drained into. However, although the volleyball structure of the fixed frame 200 is not shown in FIG. 15 for convenience, it may be configured in the same manner as the volleyball structure described with reference to FIGS. 4 and 6.

As shown in FIG. 15, the fixed frame may be configured to be divided into an indoor fixed frame 200 and an external cover shield gasket 500 which is an outdoor fixed frame. It is composed of two parts as described above, and the first elastic part 504 for sealing the gap between the opening 110 and the outer cover shield gasket 500, which is an outdoor fixed frame, is provided, and the glass plate 100 is in close contact. By providing the second elastic portion 506, the shield gasket also functions. When the fixing frame is composed of two parts in this way, the indoor fixing frame 200 is fixed by attaching it using structural silicone 121 between the outer flange 202 and the glass plate 110. When taking out for the repair of the fixed frame 200, only the structural silicon 121 is removed and the fixed frame 200 can be easily taken out to the interior.

Further, the outer cover shield gasket 500 may be formed of a material such as rubber packing, but may also be formed of a plastic material having elasticity. However, in the case of a plastic kick material, the first elastic portion 504 and the second elastic portion 506 are attached separately, and it is preferable to be composed of a silicone or rubber packing material used for the shield gasket. Therefore, it is preferable that the outer cover shield gasket 500 is integrally formed of a material having a small elasticity, such as a rubber material or a silicone material.

18 is a schematic illustration of the structure of the elastic part of the outer cover shield gasket according to another embodiment of the present invention.

On the other hand, the first elastic portion 504 and the second elastic portion 506 may be configured as a closed elastic portion having an empty space therein as shown in FIG. 15, but the first elastic portion 504 is a wing-shaped protrusion The second elastic portion 506 may be configured by folding the tip in an arc shape.

Accordingly, when the fixed frame is composed of the indoor fixed frame 200 and the outdoor outer cover shield gasket 500, there is no need to insert and install a separate shield gasket, and the indoor for repair of the fixed frame 200 There is an effect that can be easily removed from the side.

Meanwhile, the indoor ventilation system forms an opening 110 in the window pane 100, installs a fixed frame 200 in the opening 110, and uses a fixed frame 200 in the fixed frame 200 using the operation part 300 ( 200) to open or close the ventilation window by closing or opening it. However, the window glass 100 may be composed of a single tempered glass plate, but may be composed of multiple glass plates for insulation effect.

If the opening 110 is formed in the case where the window pane is composed of multiple glass plates, a spacer must be inserted and sealed to maintain a gap between the glass plate and the glass plate. If the spacer is composed of independent parts, the number of parts increases and installation work can be cumbersome.

In view of this, as another embodiment of the present invention, a configuration in which a spacer is integrally formed on a fixed frame is provided.

19 is a schematic cross-sectional view showing the configuration of an indoor ventilation system having a fixed spacer-integrated frame structure according to the present invention.

The fixed frame 200, a cylindrical portion 201 protruding outwardly into the opening 110, an outer flange 202 protruding outwardly from the tip of the cylindrical portion 201, an outer flange 202 ), the inner flange 203 protruding to the inner periphery is formed. It characterized in that the annular spacer 205 is formed on the outer periphery of the cylindrical portion 201 of the fixed frame 200.

The spacer 205 is a spacer supporting a gap between two glass plates 100 and is integrally formed on the fixed frame 200.

The opening 110 is formed in the window pane 100. The window glass 100 was exemplified as being composed of two glass plates. In a triple glass window in which three glass plates are arranged, two spacers may be integrally formed on the fixed frame 200.

When the fixed frame-integrated spacer 205 is provided, the spacer 205 is disposed between two glass plates, but the third shield ring 122c is inserted inside the spacer 205 to seal the spacer 205. ) Is installed. Separated first and second shield rings 122a and 122b are installed on the left and right sides of the spacer 205, respectively. Then, a shield material 121 is inserted and attached between the outer flange 203 of the fixed frame 200 and the glass plate.

The first to third shield rings 122a, 122b, and 112c may be preformed shield rings. The first and second shield rings 122a and 122b are pre-formed shield rings, and the third shield ring 122c may be a shield material that is injected with liquid silicon to shield. Alternatively, both the first to third shield rings may be shield materials for injecting liquid silicon. In the manufacturing process, preferably, liquid silicon is injected to form the shielding material 121 and the first to third shielding rings 122a to 123c.

As described above, in the case where the spacer is integrally formed on the fixed frame, a glass window equipped with an indoor ventilation system can be produced in a factory rather than on-site installation. Since the spacer 205 is integrally formed on the fixed frame 200, it is possible to reduce the number of parts and simplify the process, thereby reducing manufacturing cost. When the fixed frame is formed of a high-strength special material, it can be used semi-permanently, and the external force applied to the opening of the glass plate is distributed to the integral spacer and the fixed frame, thereby improving safety strength.

Although the present invention has been described in detail in the above embodiments, it is obvious that the present invention is not limited thereto, and it is apparent to those skilled in the art that various modifications and modifications are possible within the technical scope of the present invention. If it falls within the scope of the claims, the technical idea should also be regarded as belonging to the present invention.

100: window pane 110: opening
120: first shield gasket
200: fixed frame
201: cylindrical portion 202: outer flange
203: inner flange 203a: insertion groove
210: second shield gasket 211: second gutter
221: first gutter 231: barrier
241: drain groove 242: drain hole
260: hook
300: operating unit
301: cylindrical portion 302: flange
303: engaging portion 331: blocking wall
332: guider 305: bottom surface
400: filter
500: outer cover shield gasket

Claims (6)

In the indoor ventilation system comprising an operating portion for opening the opening in the window glass, the fixed frame is installed in close contact with the opening, and the opening or closing of the ventilation window by inserting or pulling out the fixed frame,
A second gutter for inserting a shield gasket is formed on an outer flange of the fixed frame, and a second shield gasket is inserted into the second gutter to seal between the fixed frame and the operation part,
The second shield gasket,
An indoor ventilation system comprising a body part inserted into the second gutter and a wing part protruding outwardly from the body part.
The method according to claim 1,
The second shield gasket,
A plurality of protrusions are further formed around the body portion, and the indoor ventilation system is characterized in that it is installed by being pressed against a sidewall of the second gutter.
The method according to claim 1,
The side wall of the second gutter, the indoor ventilation system, characterized in that the projection formed on the body portion of the second shield gasket is further formed with a locking projection to ride over.
The method according to claim 1,
In the side wall of the second gutter, an indoor ventilation system, characterized in that a groove portion into which a protrusion formed in the body portion of the second shield gasket is inserted is further formed.
The method according to claim 1,
An inner flange corresponding to the outer flange is further formed on the fixed frame, and a plurality of insertion grooves are formed on the inner flange,
On the outer peripheral surface of the cylindrical portion of the operation portion, a plurality of coupling portions passing through the insertion groove and engaging the inner flange by rotation of the operation portion are further formed,
The indoor ventilation system, characterized in that the flange of the operation portion is in close contact with the second shield gasket to seal the connection between the fixed frame and the operation portion by inserting the operation portion into the fixed frame and rotating to fix the coupling portion.
The method according to claim 1,
A locking hook is formed at the distal end of the cylindrical portion of the operation unit,
The fixing frame is further formed with an inner flange protruding from the inner periphery of the tip of the cylindrical portion,
An indoor ventilation system, characterized in that the moving part is pulled out of the fixed frame and the movable frame is mounted on the inner flange by hanging the working hook.

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