KR102820978B1 - Plastic window with composite insulation structure and method for manufacturing the same - Google Patents

Abstract

The present invention relates to a plastic window having a composite insulation structure that is implemented to improve insulation and soundproofing performance while maintaining support for a glass load, and a method for manufacturing the same, the window comprising: a first frame having a square hollow cross-section and a first joining portion formed at a front end; a second joining portion arranged spaced forward from the first frame and symmetrically provided toward the first joining portion with respect to the first joining portion; a pair of glass panel parts installed at the front end of the first frame while being spaced apart from each other while being symmetrical above and below; a composite insulation part installed in a spaced space between the pair of glass panel parts; and a second frame installed to cover the front end of the second joining portion and between the pair of glass panel parts.

Description

Plastic window with composite insulation structure and method for manufacturing the same {Plastic window with composite insulation structure and method for manufacturing the same}

The present invention relates to a plastic window having a composite insulation structure and a method for manufacturing the same, and more specifically, to a plastic window having a composite insulation structure implemented so as to improve insulation and soundproofing performance while maintaining support for glass load, and a method for manufacturing the same.

As buildings become taller or more super tall, there is a demand to reduce the dead weight of buildings and make them lighter.

The weight reduction of these high-rise buildings leads to a reduction in construction costs through shortened construction periods, reduced use of materials, and shortened time. The most common method of achieving this is curtain wall construction, which is quick and easy to construct.

A curtain wall is a non-load-bearing wall of a building that protects residents from the outside environment without supporting the building's load. The vertical load applied to the building and the horizontal load caused by wind or earthquakes are supported by the frame made of columns and beams, and the curtain wall acts as a curtain to protect the residents inside the building from the outside environment.

These curtain walls are constructed by erecting vertical and horizontal curtain wall structures and inserting glass walls between the curtain wall structures. Since wrapping the exterior wall surface of a building with glass walls and curtain wall windows is relatively inexpensive compared to finishing it with concrete or other exterior finishing materials, its use is gradually increasing.

Recently, as national policies such as energy conservation and efficiency are applied to buildings, energy efficiency ratings for buildings are being certified, and as conventional curtain walls are applied to modern buildings with increasing window area ratios, energy-related restrictions and limitations are gradually increasing.

Meanwhile, the background technology described above is technical information that the inventor possessed for deriving the present invention or acquired during the process of deriving the present invention, and cannot necessarily be considered as publicly known technology disclosed to the general public prior to the application of the present invention.

Korean Patent Registration No. 10-1177265 (Publicly Announced on August 28, 2012)

One aspect of the present invention provides a plastic window having a composite insulating structure that can improve insulation and soundproofing performance while maintaining support for glass load, and a method for manufacturing the same.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

A plastic window having a composite insulation structure according to one embodiment of the present invention comprises: a first frame having a square hollow cross-section and a first connecting portion formed at a front end; a second connecting portion spaced forwardly from the first frame and provided symmetrically with the first connecting portion toward the first connecting portion; a pair of glass panel portions installed at the front end of the first frame while being spaced apart from each other and being symmetrical up and down; a composite insulation portion installed in a spaced space between the pair of glass panel portions; and a second frame installed to cover the front end of the second connecting portion and between the pair of glass panel portions.

In one embodiment, the second frame may include an outer frame removably coupled to a portion of the second coupling portion opposite the portion facing the first coupling portion; and a closing frame slidably coupled to a portion of the outer frame opposite the portion to which the second coupling portion is coupled.

In one embodiment, the composite insulation member may include: an insulating composite member provided between the first joining member and the second joining member between the pair of glass panel members, the upper and lower portions being spaced apart from each other, while the spaced space between the upper and lower portions has a plurality of insulating partitions provided in an alternating manner on the upper and lower portions so as to form an air layer in an upper and lower zigzag manner; an insulating gasket provided between the first frame and the glass panel member and between the outer frame and the glass panel member, the insulating gasket being provided symmetrically in the upper, lower, left, and right directions to simultaneously block air flow and heat flow; an airtight member provided in the spaced space between the insulating gaskets that are vertically adjacent; and a soundproof member provided in an upper and lower pair between the outer frame and each of the pair of glass panel members so that the space in which the insulating composite member is installed is isolated from the space in which the glass panel member is installed, and the space in which the glass window of each of the glass panel members is also isolated from each other.

In one embodiment, a plastic window having a composite insulation structure according to one embodiment of the present invention may further include a silicone finishing portion that is filled to seal between the pair of glass panel portions and the first frame and the second frame, respectively.

In one embodiment, a plastic window having a composite insulation structure according to another embodiment of the present invention may further include a multi-functional blower module installed at the front end of the second frame to blow wind toward the pair of glass panel portions to remove foreign substances and at the same time prevent the pair of glass panel portions from overheating.

In one embodiment, the multi-functional blower module may include a module frame having a triangular prism shape and installed at the front end of the second frame; a pair of sliding rail grooves extending along two front end slopes of the module frame; a pair of rail frames each installed in the pair of sliding rail grooves; a pair of blower units arranged in the sliding rail grooves while engaging with the rail frames and blowing wind toward the glass panel portion while sliding along the sliding rail grooves; and a pair of rail groove covers installed and covering one side of the sliding rail grooves so as to accommodate the blower units.

In one embodiment, the blower unit may include: a slider that is interlocked and connected to the rail frame and slides along the sliding rail groove; a unit body portion that is formed in a square flat plate shape and is connected to the slider and slides along the sliding rail groove together with the slider or is stored in a storage space formed by the rail groove cover, and rotates about the rail frame as a rotation axis so as to face the glass panel portion; a rotational drive gear that is interlocked and connected by the slider gear engagement and rotates forward or reversely to rotate the unit body portion; a fan housing formed while penetrating the unit body in a circular shape; a blower fan that is installed inside the fan housing and blows wind through the fan housing; a fan mounting portion that mounts the blower fan inside the fan housing; and a concentrating induction portion that is installed along the front end of the unit body portion through which wind is discharged of the fan housing and concentrates wind discharged through the blower fan.

In one embodiment, the concentrated induction unit comprises: a ring-shaped mounting groove formed hollow in a circular ring shape along the inner side of the unit body while surrounding the fan housing; an inclined groove formed so as to be connected from a front end of the ring-shaped mounting groove to a front end of the unit body, but formed so as to be gradually inclined so as to have a diameter that gradually decreases as it goes forward; a plurality of elastic frames arranged at regular intervals along the ring-shaped mounting groove, made of a bendable elastic material, moved forward from the ring-shaped mounting groove, passed through the inclined groove, and then exposed to the front of the unit body, but bent corresponding to an inclination angle of the inclined groove while passing through the inclined groove, and then exposed so as to be inclined to the front of the unit body; And it may include an elastic cover made of a thin film of an elastic material that is expandable and contractible, installed along the inward surface of the plurality of elastic frames, and when the plurality of elastic frames are exposed to the front of the unit body, they are exposed together sufficiently to cover a portion of the opening of the fan housing, thereby forming a cone-shaped passage through which wind discharged through the fan housing is discharged.

In one embodiment, the fan mounting portion may include: a plurality of mounting frames, which are radially arranged and installed upright at regular intervals along a circumference of a fan driving motor for driving the blower fan, to mount the blower fan on the inside of the fan housing; a plurality of frame mounting portions that are formed in communication from the ring-shaped mounting groove to an inward surface of the fan housing so that the mounting frame can move forward and backward along the ring-shaped mounting groove after being inserted into the ring-shaped mounting groove; and a frame driving gear that is rotatably connected to one side of the mounting frame, is interlocked with a gear mounting groove formed along one side of the frame mounting portion by gear engagement, and is rotatably driven in a forward or reverse direction to move the mounting frame forward and backward along the frame mounting portion.

In one embodiment, the fan housing may be formed so that the opening gradually expands toward the front to allow the exhausted air to spread.

In one embodiment, the concentrated induction unit may further include a guide projection formed of the same elastic material as the elastic frame and protruding along an outward surface of the elastic frame; and a guide groove formed extending along an outward surface of the ring-shaped mounting groove and an outward surface of the inclined groove, on which the elastic frame is arranged so that the guide projection is mounted and can move.

A method for manufacturing a plastic window having a composite insulation structure according to one embodiment of the present invention comprises: a first installation step of installing a first frame having a rectangular hollow cross-section and a first joint formed at a front end; a second installation step of installing a second joint that is spaced forward from the first frame and is provided symmetrically with respect to the first joint toward the first joint; a third installation step of installing a pair of glass panel parts that are installed at the front end of the first frame while being spaced apart from each other and symmetrically above and below; a fourth installation step of installing a composite insulation part that is installed in a spaced space between the pair of glass panel parts; and a fifth installation step of installing a second frame that is installed to cover the front end of the second joint part and between the pair of glass panel parts.

According to one aspect of the present invention described above, it is possible to improve insulation and soundproofing performance while maintaining support for glass load.

The effects of the present invention are not limited to the effects mentioned above, and various effects may be included within a range obvious to those skilled in the art from the contents described below.

FIGS. 1 to 3 are drawings schematically illustrating the configuration of a plastic window having a composite insulation structure according to one embodiment of the present invention.
FIG. 4 is a drawing schematically illustrating the configuration of a plastic window equipped with a composite insulation structure according to another embodiment of the present invention.
Figure 5 is a drawing showing the multi-functional blower module of Figure 4.
Figure 6 is a drawing showing the blower unit of Figure 5.
Figures 7 and 8 are drawings showing the fan mounting portion and the concentrated induction portion of Figure 6.
FIG. 9 is a drawing schematically illustrating the configuration of a plastic window having a composite insulation structure according to one embodiment of the present invention.

The detailed description of the invention set forth below refers to the accompanying drawings which illustrate, by way of example, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the invention, while different from one another, are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention. It should also be understood that the positions or arrangements of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly so described. Like reference numerals in the drawings designate the same or similar functionality throughout the several aspects.

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

FIGS. 1 to 3 are drawings schematically illustrating the configuration of a plastic window having a composite insulation structure according to one embodiment of the present invention.

Referring to FIGS. 1 to 3, a plastic window (10) equipped with a composite insulation structure according to one embodiment of the present invention includes a first frame (100), a second connecting portion (200), a pair of glass panel portions (300-1, 300-2), a composite insulation portion (400), and a second frame (500).

The first frame (100) has a hollow shape with a square cross section, and a first connecting portion (110) is formed at the front end.

The second connecting portion (200) is positioned forwardly away from the first frame (100) and is provided symmetrically with respect to the first connecting portion (110) toward the first connecting portion (110).

A pair of glass panel sections (300-1, 300-2) are installed at the front end of the first frame (100) while being symmetrical and spaced apart from each other.

The composite insulation member (400) is installed in the space between a pair of glass panel members (300-1, 300-2).

In one embodiment, the composite insulation (400) may include an insulating composite member (410), an insulating gasket (420), a sealing member (430), and a soundproofing member (440).

An insulating composite member (410) is provided between a first joining member (110) and a second joining member (200) between a pair of glass panel members (300-1, 300-2), and the upper and lower parts are spaced apart from each other, but the spaced space between the upper and lower parts is provided with a plurality of insulating partitions that are staggered from each other to form an air layer in an upper and lower zigzag pattern.

The insulating gasket (420) is provided between the first frame (100) and the glass panel portion (300) and between the outer frame (510) and the glass panel portion (300), and is provided symmetrically in the upper, lower, left, and right directions to simultaneously block the flow of air and heat.

The confidentiality member (430) is provided in the space between the upper and lower adjacent insulating gaskets (420).

Soundproofing members (440) are provided as a pair of upper and lower members between the outer frame (510) and each of a pair of glass panel sections (300-1, 300-2) so that the space where the insulating composite member (410) is installed is isolated from the space where the glass panel section (300) is installed, and the space where the glass window of each of the glass panel sections (300) is installed is also provided so that it is isolated from each other.

The second frame (500) is installed to cover the front end of the second joint portion (200) and between a pair of glass panel portions (300-1, 300-2).

In one embodiment, the second frame (500) may include an outer frame (510) and a closing frame (520).

The outer frame (510) is detachably connected to the opposite side of the second connecting portion (200) toward the first connecting portion (110).

The closing frame (520) is slidably and detachably connected to the opposite side of the outer frame (510) where the second connecting portion (200) is connected.

A plastic window (10) equipped with a composite insulation structure according to one embodiment of the present invention having the configuration described above may further include a silicone finishing portion (S).

The silicone sealing portion (S) is filled to seal the space between a pair of glass panel portions (300-1, 300-2) and the first frame (100) and the second frame (500).

A plastic window (10) equipped with a composite insulation structure according to one embodiment of the present invention having the configuration described above can improve insulation and soundproofing performance while maintaining support for glass load.

FIG. 4 is a drawing schematically illustrating the configuration of a plastic window equipped with a composite insulation structure according to another embodiment of the present invention.

Referring to FIG. 4, a plastic window (20) equipped with a composite insulation structure according to another embodiment of the present invention includes a first frame (100), a second joining portion (200), a pair of glass panel portions (300-1, 300-2), a composite insulation portion (400), a second frame (500), and a multi-functional blower module (600).

Here, the first frame (100), the second connecting portion (200), the pair of glass panel portions (300-1, 300-2), the composite insulation portion (400), and the second frame (500) are identical to the components of Fig. 1, so their descriptions are omitted to avoid duplication of explanation.

A multi-functional blower module (600) is installed at the front end of the second frame (500) and blows wind toward a pair of glass panel sections (300-1, 300-2) to remove foreign substances and prevent the pair of glass panel sections (300-1, 300-2) from overheating.

In one embodiment, a multi-function blower module (600) may include a module frame (610), a pair of sliding rail grooves (620), a pair of rail frames (630), a pair of blower units (640), and a pair of rail groove covers (650).

The module frame (610) is formed in a triangular prism shape and is installed at the front end of the second frame (500), and is configured with a pair of sliding rail grooves (620), a pair of rail frames (630), a pair of blower units (640), and a pair of rail groove covers (650).

A pair of sliding rail homes (620) are formed to extend along two shear slopes of the module frame (610) so that the blower unit (640) can be installed and slide.

A pair of rail frames (630) are each installed in a pair of sliding rail grooves (620) so that a blower unit (640) can be interlocked and moved.

A pair of blower units (640) are interlocked with the rail frame (630) and arranged in a sliding rail home (620), and blow wind toward the glass panel portion (300) while sliding along the sliding rail home (620).

A pair of rail home covers (650) are installed to cover one side of the sliding rail home (620) so that the blower unit (640) can be accommodated.

A plastic window (20) equipped with a composite insulation structure according to another embodiment of the present invention having the configuration described above can effectively prevent dust and the like that may adhere to a pair of glass panel parts (300-1, 300-2) by blowing wind through each of the pair of glass panel parts (300-1, 300-2), and also effectively prevent the pair of glass panel parts (300-1, 300-2) from overheating in the summer.

Figure 6 is a drawing showing the blower unit of Figure 5.

Referring to FIG. 6, the blower unit (640) includes a slider (641), a unit body (642), a rotation driving gear (643), a fan housing (644), a blower fan (645), a fan mounting part (700), and a concentrated induction part (800).

The slider (641) is installed so as to be interlocked and connected to the rail frame (630) and slides along the sliding rail home (620), and is installed so as to be interlocked and connected so as to be rotatable with the unit body (642).

The unit body (642) is formed into a square flat plate shape and is connected to a slider (641) and moves along a sliding rail home (620) together with the slider (641) or is stored in a storage space formed by a rail home cover (650). The unit body (642) is rotated by a rotational drive gear (643) with the rail frame (630) as a rotation axis so as to face the glass panel portion and rotate to face the glass panel portion (300).

The rotation drive gear (643) is installed so as to be rotationally driven on the inside of the unit body (642) and is connected by meshing with the slider (641) gear combination, and rotates in the forward or reverse direction to drive the unit body (642) in rotation.

The fan housing (644) is formed by penetrating the unit body (642) in a circular shape so that a blower fan (645) can be installed.

In one embodiment, the fan housing (644) may be formed so that the opening (6441) gradually expands toward the front to allow the exhausted wind to spread, as illustrated in FIG. 7.

The blower fan (645) is installed on the inside of the fan housing (644) by the fan mounting part (700) and blows wind through the fan housing (644).

The fan mounting portion (700) mounts a blower fan (645) on the inside of the fan housing (644).

The concentrating induction unit (800) is installed along the front end of the wind exhaust unit body (642) of the fan housing (644) and concentrates the wind exhausted through the blower fan (645).

The blower unit (640) having the configuration described above can be stored in a storage space partitioned by a rail home cover (650) when not in operation and protected from the external environment, and when in operation, it slides to be exposed from the storage space, then rotates toward the panel portion (300), and then moves back and forth while blowing wind to remove dust, etc. attached to the panel portion (300) and prevent the panel portion (300) from overheating.

Figures 7 and 8 are drawings showing the fan mounting portion and the concentrated induction portion of Figure 6.

Referring to FIGS. 7 and 8, the concentrated induction unit (800) includes a ring-shaped mounting groove (810), an inclined groove (820), a plurality of elastic frames (830), and an elastic cover (840).

The ring-shaped mounting groove (810) is formed hollow in a circular ring shape along the inner side of the unit body (642) while surrounding the fan housing (644).

The inclined groove (820) is formed so as to be connected from the front end of the ring-shaped fixing groove (810) to the front end of the unit body (642), but is formed so as to be inclined so that the diameter gradually decreases as it goes forward.

A plurality of elastic frames (830) are arranged at regular intervals along the ring-shaped mounting groove (810), and are made of a bendable elastic material so as to move forward from the ring-shaped mounting groove (810), pass through the inclined groove (820), and are exposed toward the front of the unit body (642), but while passing through the inclined groove (820), are bent in response to the inclination angle of the inclined groove (820), and are exposed so as to be inclined toward the front of the unit body (642).

The elastic cover (840) is made of a thin film of an elastic material that can expand and contract, and is installed along the inward surface of a plurality of elastic frames (830). As the plurality of elastic frames (830) are exposed toward the front of the unit body (642), they are exposed together enough to partially cover the opening of the fan housing (644), thereby forming a cone-shaped passage through which wind discharged through the fan housing (644) is discharged.

The concentrated induction unit (800) having the configuration described above may further include a guide protrusion (850) and a guide groove (860).

The guide protrusion (850) is made of the same elastic material as the elastic frame (830) and is formed to protrude along the outward surface of the elastic frame (830).

The guide home (860) is formed to extend along the outward surface of the ring-shaped mounting home (810) and the outward surface of the inclined groove (820) in which the elastic frame (830) is arranged so that the guide protrusion (850) can be mounted and moved.

Referring to FIGS. 7 and 8, the fan mounting portion (700) includes a plurality of mounting frames (710), a plurality of frame mounting portions (720), and a frame driving gear (730).

A plurality of mounting frames (710) are installed upright in a radial arrangement at regular intervals along the periphery of a fan driving motor for driving a blower fan (645) and support the blower fan (645) on the inside of the fan housing (644).

A plurality of frame mounting portions (720) are formed in communication from the ring-shaped mounting groove (810) to the inward surface of the fan housing (644) so that the mounting frame (710) can move forward and backward along the ring-shaped mounting groove (810) after being inserted into the ring-shaped mounting groove (810).

The frame drive gear (730) is installed so as to be rotatably connected to one side of the mounting frame (710), and is connected by gear engagement to a gear mounting groove formed along one side of the frame mounting portion (720), and rotates forward or reversely to move the mounting frame (710) forward and backward along the frame mounting portion (720).

FIG. 9 is a diagram schematically illustrating a configuration of a method for manufacturing a plastic window having a composite insulation structure according to one embodiment of the present invention.

Referring to FIG. 9, a method for manufacturing a plastic window equipped with a composite insulation structure according to one embodiment of the present invention is a method for installing a plastic window (10, 20) equipped with a composite insulation structure described above in FIGS. 1 to 8, in which a first frame (100) having a square hollow cross-section and a first connecting portion (110) formed at the front end is installed (S110).

A second coupling part (200) is installed (S120) spaced forward from the first frame (100) and symmetrically positioned toward the first coupling part (110) with respect to the first coupling part (110).

A pair of glass panel parts (300-1, 300-2) are installed on the front end of the first frame (100) while being symmetrical and spaced apart from each other (S130).

A composite insulation member (400) is installed in the space between a pair of glass panel members (300-1, 300-2) (S140).

A second frame (500) is installed to cover the front end of the second joint portion (200) and between a pair of glass panel portions (300-1, 300-2) (S140).

A second frame (500) is installed to cover the front end of the second joint (200) and between a pair of glass panel sections (300-1, 300-2) (S150).

A method for manufacturing a plastic window having a composite insulation structure according to one embodiment of the present invention having the steps described above,

A sixth installation step (not shown in the drawing for convenience of explanation) of installing a multi-functional blower module (600) at the front end of the second frame (500) may be further included.

The above-described embodiments are for illustrative purposes, and those skilled in the art will appreciate that the above-described embodiments can be easily modified into other specific forms without changing the technical idea or essential features of the above-described embodiments. Therefore, the above-described embodiments should be understood as illustrative and not restrictive in all respects. For example, each component described as a single entity may be implemented in a distributed manner, and likewise, components described as distributed may be implemented in a combined manner.

The scope of protection sought by this specification is indicated by the claims described below rather than the detailed description above, and should be interpreted to include all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts.

10, 20: Plastic windows with composite insulation structure
100: 1st frame
200: Second joint
300: Glass panel section
400: Composite insulation
500: 2nd frame

Claims (5)

A first frame having a rectangular hollow cross-section and a first connecting portion formed at the front end;
A second coupling part is positioned forwardly from the first frame and is provided symmetrically with respect to the first coupling part toward the first coupling part;
A pair of glass panel sections installed at the front end of the first frame while being symmetrical and spaced apart from each other;
A composite insulation member installed in the space between the above pair of glass panel members;
A second frame installed to cover the front end of the second joint portion and between the pair of glass panels; and
A multi-functional blower module is installed at the front end of the second frame to blow wind toward the pair of glass panels to remove foreign substances and prevent the pair of glass panels from overheating;
The above multi-functional blower module,
A module frame having a triangular prism shape and installed at the front end of the second frame;
A pair of sliding rail grooves formed extending along two shear slopes of the above module frame;
A pair of rail frames each installed in the above pair of sliding rail homes;
A pair of blower units interlocked with the above rail frame and arranged in the above sliding rail home, and blowing wind toward the glass panel portion while sliding along the above sliding rail home; and
A pair of rail home covers are installed to cover one side of the sliding rail home so that the blower unit can be stored;
The above blower unit,
A slider that is installed and interlocked with the above rail frame and slides along the sliding rail home;
A unit body part formed in a square flat plate shape, connected to the slider, and sliding along the sliding rail home together with the slider or stored in a storage space formed by the rail home cover, and rotating about the rail frame as a rotation axis so as to face the glass panel part;
A rotational drive gear that is installed so as to be rotatably driven on the inside of the unit body and is connected and interlocked by the slider gear combination, and rotates in the forward or reverse direction to drive the unit body to be rotated;
A fan housing formed by penetrating the above unit body in a circular shape;
A blower fan installed inside the fan housing and blowing wind through the fan housing;
A fan mounting portion for mounting the blower fan on the inside of the fan housing; and
It includes a concentrating induction unit installed along the front end of the unit body part through which the wind of the fan housing is discharged and which concentrates the wind discharged through the blower fan;
The above-mentioned concentrated induction unit is,
A ring-shaped mounting groove formed hollow in a circular ring shape along the inner side of the unit body while surrounding the fan housing;
An inclined groove formed so as to be connected from the front end of the ring-shaped fixing groove to the front end of the unit body, but having a gradually decreasing diameter as it goes forward;
A plurality of elastic frames are arranged at regular intervals along the ring-shaped fixing groove, made of a bendable elastic material, and are exposed to the front of the unit body after moving forward from the ring-shaped fixing groove and passing through the inclined groove, and are exposed to the front of the unit body after being bent in response to the inclination angle of the inclined groove while passing through the inclined groove; and
An elastic cover is formed of a thin film of an elastic material that can expand and contract, and is installed along the inward surface of the plurality of elastic frames, and the plurality of elastic frames are exposed together so as to sufficiently cover a portion of the opening of the fan housing as they are exposed to the front of the unit body, thereby forming a cone-shaped passage through which wind discharged through the fan housing is discharged;
The above fan mount is,
A plurality of mounting frames, each of which is installed radially and upright at regular intervals along the circumference of the fan drive motor for driving the blower fan, and which support the blower fan on the inside of the fan housing;
A plurality of frame mounting portions formed in communication from the ring-shaped mounting groove to the inward surface of the fan housing so that the above-mentioned mounting frame can move forward and backward along the ring-shaped mounting groove after being inserted into the ring-shaped mounting groove; and
A plastic window with a composite insulation structure, comprising: a frame driving gear that is installed so as to be rotatably connected to one side of the above-mentioned mounting frame, is connected and interlocked by gear engagement in a gear mounting groove formed along one side of the above-mentioned frame mounting portion, and rotates forward or backward to move the above-mentioned mounting frame forward and backward along the above-mentioned frame mounting portion.
In the first paragraph,
The second frame above,
An outer frame detachably coupled to the opposite side of the second coupling portion toward the first coupling portion; and
A plastic window having a composite insulation structure, comprising a finishing frame that is slidably and detachably connected to a portion opposite to the portion where the second connecting portion is connected in the outer frame.
In the second paragraph,
The above composite insulation part is,
An insulating composite member provided between the first joining portion and the second joining portion between the pair of glass panel portions, the upper and lower portions being spaced apart from each other, and the spaced space between the upper and lower portions having a plurality of insulating partitions provided in an alternating manner on the upper and lower portions so as to form an air layer in an upper and lower zigzag pattern;
An insulating gasket provided between the first frame and the glass panel portion, and between the outer frame and the glass panel portion, and provided symmetrically in the upper, lower, left, and right directions to simultaneously block the flow of air and heat;
A sealing member provided in the space between the upper and lower adjacent insulating gaskets among the above insulating gaskets; and
A plastic window having a composite insulating structure, comprising: a soundproofing member provided as a pair of upper and lower members between the outer frame and each of the pair of glass panel sections so that the space in which the insulating composite member is installed is isolated from the space in which the glass panel sections are installed, and so that the space in which the glass windows of each of the glass panel sections are installed is also isolated from each other.
In the first paragraph,
A plastic window having a composite insulating structure, further comprising a silicone finishing portion that is filled to seal between the pair of glass panel portions and the first frame and the second frame.
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