KR20140033599A - Ridge of a roof of glasshouse - Google Patents

Abstract

A ridge of a roof combination structure for a glasshouse according to the present invention enables a window (5) on a roof (1) to be opened and closed as a window unit (200) is rotated. As the opened and closed window unit (200) and the roof (1) are hermetically sealed, thereby blocking the temperature difference between the indoor and outdoor; the occurrence of condensation can be minimized.

Description

{Ridge of a roof of Glasshouse}

The present invention relates to a ridge joint structure of a glasshouse, and more particularly, to a ridge-joint structure of a glasshouse, which minimizes the occurrence of condensation through effective heat insulation and inserts an insertion gasket in a direction parallel to the glass, The present invention relates to a ridge coupling structure of a glasshouse.

Generally, glass greenhouses are used for cultivating various plants or crops by providing artificial growth conditions, and they are constructed on various structures made of glass which is easy to transmit light.

In the case of such a glass greenhouse, it largely consists of a side wall means of the greenhouse, a roof means and a roof means provided at a predetermined interval at the roof means and opened and closed.

Wherein the roof means is provided with a plate glass by means of a rafter member so as to be inclined to the side lower side of a ridge member provided at the upper center of the ridge member, and the ridge means comprises a roof raster member rotatably installed on the ridge member, And the side wall means is installed in a state in which the plate glass is joined by a vertical member to form a glass greenhouse.

Conventional rafter glass fixing devices in which the plate glass is fixedly installed in such a glass greenhouse are not compatible with each other by using a method of fixing them by means of an aluminum cover with a piece and a method of fixing them directly with a rubber material cover, There was.

Further, in the case of fixing the aluminum cover with the pieces, the fastening groove formed at the center of the rafter and the aluminum cover are fastened with the pieces, so that the pieces are easily unwound from the fastening holes. There is a problem in that leakage occurs due to separation of the coupling portion or generation of a gap in the coupling portion.

It is an object of the present invention to provide a ridge coupling structure of a glass greenhouse having a simple construction method by minimizing the occurrence of condensation through effective heat insulation and sandwiching an insertion gasket in a direction parallel to the glass so that generated condensation can be drained easily have.

The present invention is a ridge coupling structure of a glass greenhouse in which a ridge 310 is disposed and a roof 1 is formed such that a window 5 opened to the outside is formed. The ridge 310 is installed, A roof unit 300 including a roof 1 including a flat sealing unit 100 formed by connecting the roof unit 1 and the roof unit 1; And a window unit (200) coupled to the roof unit (300) and opening and closing a part of the roof (1) while rotating at a predetermined angle, wherein the roof unit (300) comprises a main frame (310); And a flat sealing unit 100 which is tightly coupled to the crest 330 and is formed by connecting a plurality of glasses 22 and 24 to each other.

The ridge 310 includes an upper frame body 320 to which the window unit 200 is coupled; A lower frame body 330 coupled to the upper frame body 320 and secured to the main frame 10 supporting the glasshouse; And a heat insulating member 316 disposed between the upper frame body 320 and the lower frame body 330 to insulate the inside and the outside of the lower frame body 320.

The upper frame body 320 is fixed to the lower frame body 330 and a rotation hook 322 for relative rotation with the window unit 200 may be formed.

The window unit (200) includes a window frame (210) coupled to the rotation hooks (322) provided on the left and right sides of the upper frame body (320) and rotated. A window cover 220 for shielding the respective window frames 210 by connecting them; And the flat sealing unit 100 installed on each of the window frames 210 to shield the window 5 of the roof 1.

The window frame 210 includes a window hanger 212, which is coupled to the rotation hanger 322 in a hooked manner and rotated. A flat contact portion 214 which is in close contact with an upper surface of the flat sealing unit 100 of the roof unit 100; And a cover coupling part 216 to which the window cover 220 is coupled.

The ridge coupling structure of the glasshouse according to the present invention can open and close the window 5 of the roof 1 while the window unit 200 is rotated and the window unit 200 and the roof 1, It is possible to minimize the occurrence of condensation by shutting off the indoor and outdoor temperature difference.

Since the ridge coupling structure of the glass greenhouse according to the present invention is installed by inserting the insertion gasket 52 in the direction parallel to the glass in the window unit 200 and the flat sealing unit 100 forming the roof, Since the construction is simple and the gap between the plurality of glasses connected in a planar manner is sealed by using the single insertion gasket 52, moisture penetration and heat loss due to the seam are fundamentally cut off.

1 is a perspective view of a glass greenhouse according to an embodiment of the present invention.
Fig. 2 is a partially cut-away section view showing the ridge coupling structure shown in Fig.
3 is a cross-sectional view of the ridge joint structure shown in Fig. 2,
Fig. 4 is an enlarged view of a portion IV shown in Fig. 2
Figure 5 is a partial perspective view of the ridge coupling structure shown in Figure 2;
Fig. 6 is a cross-sectional view of the closed state of the roof and window unit shown in Fig. 2
Fig. 7 is a perspective view of the window shown in Fig. 2,
Fig. 8 is a partially cutaway perspective view of the flat sealing unit shown in Fig.
9 is a front cross-sectional view of FIG.
Fig. 10 is an exploded perspective view of Fig. 8
11 is a front view of FIG. 10.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. Even if the terms are the same, it is to be noted that when the portions to be displayed differ, the reference signs do not coincide.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

The terms first, second, etc. in this specification may be used to describe various elements, but the elements should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the relevant art and are to be interpreted in an ideal or overly formal sense unless explicitly defined in the present application Do not.

Also, when a part is referred to as "including " an element, it does not exclude other elements unless specifically stated otherwise.

FIG. 1 is a perspective view showing a glasshouse according to an embodiment of the present invention, FIG. 2 is a partially cutaway cross-sectional view illustrating a ridge coupling structure shown in FIG. 1, 2 is an enlarged view of part IV shown in Fig. 2, Fig. 5 is a partial perspective view of the ridge coupling structure shown in Fig. 2, Fig. 6 is a cross- Fig. 7 is a perspective view showing the edge of the window shown in Fig. 2, Fig. 8 is a partially cutaway perspective view of the flat sealing unit shown in Fig. 2, and Fig. 9 is a cross- Fig. 10 is an exploded perspective view of Fig. 8, and Fig. 11 is a front view of Fig.

Referring to FIGS. 1 to 5, a glass greenhouse according to an embodiment of the present invention connects a plurality of glass in a planar manner to form side walls and a roof, and the illustrated joint structure of glass is installed on a frame for supporting a glasshouse Thereby blocking the outside air communication and providing a flow path for collecting condensed water generated therein and effectively discharging it.

In particular, the ridge coupling structure described below relates to a ridge coupling structure that forms a corner at the roof of a glasshouse, in which a window unit 200 is installed and can optionally open a window 5 formed in the roof 1 .

The ridge coupling structure of the glass greenhouse comprises a roof unit 300 provided with a ridge and forming a roof 1 of the glass greenhouse, and a roof unit 300 coupled to the roof unit 300, And a window unit 200 for opening and closing the window unit 200.

A window 5 opened and closed by the window unit 200 is formed on the roof 1.

The roof unit 300 includes a crest 310 fixed to the main frame 10 supporting a load of the glasshouse and a flat sealing unit 100 tightly coupled to the crest 330.

Here, the ridge 310 may be formed of one frame, but in this embodiment, it is divided into two parts, and a heat insulating member 316 is provided therebetween to improve the heat insulating performance.

Therefore, the ridge 310 includes an upper frame body 320 to which the window unit 200 is coupled, a lower frame body 320 coupled to the upper frame body 320 and fixed to the main frame 10 supporting the glasshouse, And a heat insulating member 316 disposed between the upper frame body 320 and the lower frame body 330 to insulate the inside and outside of the lower frame body 330.

The heat insulating member 316 is fixed to the upper frame body 320 and the lower frame body 330 by a fastening member 301.

The lower frame body 330 is fixed to the main frame 10 supporting the load of the glass greenhouse and is formed with a bolt insertion portion 331 for fastening to the main frame 10, And is fixed to the frame 10 by bolts 332.

The upper frame body 320 is fixed to the lower frame body 330 and is formed with a rotation hook 322 for relative rotation with the window unit 200. The rotation hook 322 includes And is formed into a hook shape such as a "J" shape. Here, the rotation hooking part 322 is formed on each of right and left sides, and the window unit 200 is coupled to the rotation hooking part 322 and can be rotated.

The upper frame body 320 is formed with a pressing portion 325 for pressing the outer body 72 of the flat sealing unit 100, which will be described later.

The flat sealing unit 100 is closely attached to both sides of the ridge 310. In this embodiment, the flat sealing unit 100 is tightly fixed to the heat insulating member 316, 100 and the crest 310 and minimizes the generation of condensation between the flat sealing unit 100 and the crest 310.

Particularly, the flat sealing unit 100 and the crest 310 are closely contacted with each other at a predetermined angle, and a ridge gasket 315 is provided for sealing. The ridge gasket 315 is disposed in the longitudinal direction of the crest 310 As shown in FIG.

8 to 11, the flat sealing unit 100 is spaced apart from the roof supporting frame 10 by a predetermined distance, and is disposed in parallel with the roof supporting frame 10, A fixing module 30 fixing the glass 22 and 24 to the roof supporting frame 10 while fixing the glass 22 and 24 to each other; And a gasket module (50) disposed between the glass (22) (24) to buffer shock applied to the glass (22) (24) and seal the inside and outside of the glass greenhouse to shut off the flow of air. .

The roof supporting frame 10 is a structure for supporting the load of the glass greenhouse.

The glass (22) (24) is arranged to form a plane to form the outer wall of the glass greenhouse, thereby forming a roof or side wall of the glass greenhouse.

The fixing module 30 is disposed inside the glass greenhouse and is disposed inside the glass 22 to support the glass 22 and 24 and is fixed to the roof supporting frame 10 And an outer frame 60 disposed on the outer side of the glass 22 and 24 and fixed to the inner frame 60 to press the glass 22 and 24 toward the inner frame 60 A fixing member 36 for fixing the inner frame 60 and the outer frame 70 and a fixing member 36 disposed between the inner frame 60 and the outer frame 70, And a supporter (38) for supporting the frame (70).

The gasket module 50 includes an insertion gasket 52 which is sandwiched between the glass 22 and the outer frame 70 and a gasket 52 which is sandwiched between the glass 22 and the inner frame 60 And a fitting gasket 54.

The inner frame 60 is fixed to the roof supporting frame 10 via bolts 61 and a nut 63. The inner frame 60 is supported by the roof supporting frame 10 and the upper side is supported by the gasket module 50, (22) (24).

The inner frame 60 includes an inner body 62 fixedly supported by the roof support frame 10 and a bolt insertion portion 64 formed in the inner body 62 and into which the head of the bolt 61 is inserted. A gasket fixing portion 65 to which the gasket module 50 is fitted and fixed and a fixing portion re-combination portion 66 to which the fixing member 36 is coupled.

The bolt insertion portion 64 is formed so that the head of the bolt can be inserted and moved in the longitudinal direction.

The gasket fixing portion 65 is for fixing the fitting gasket 54, and the gasket groove 65a is formed on the upper side.

The outer frame 70 includes an outer body 72 disposed on the upper side of the glass 22 and a gasket fixing part 72 formed on the outer body 72 and having the insertion gasket 52 inserted therein, (75) is formed.

The gasket fixing portion 75 is formed with a gasket groove 75a formed in a groove shape, and the gasket groove 75a is formed to be inclined toward the lateral direction.

The outer frame 70 includes a fixing member cover 76 for engaging the recess 74 with a recessed groove recessed downwardly through the fixing member 36, Respectively.

The supporter 38 is for pressing the gasket module 50 at a predetermined pressure when the inner frame 60 and the outer frame 70 are coupled to each other. In the present embodiment, the supporter 38 is fixed to the inner frame 60 To support the outer frame (70).

The supporter 38 includes a supporter body 38a, a supporter insertion portion 38b formed in the supporter body 38a and inserted and fixed to the fixed portion recombination portion 66, And a gasket fixing portion 38c for fixing the fitting gasket 54 to the inner frame 60.

The supporter inserting portion 38b is fixed to the inner frame 60 by the fixing member 36 after the supporter inserting portion 38b is fitted into the fixing portion re-coupling portion 66. [ The fixing member 36 penetrates through the groove 74 and the supporter 38 and is fastened to the fixed portion recombination portion 66 of the inner frame 60.

The supporter 38 is configured to support the outer frame 70 after being fixed to the inner frame 60 in the present embodiment. However, unlike the present embodiment, the supporter 38 is fitted and fixed to the outer frame 70 It may be configured to support the inner frame 60 and may be configured to be fixed by the fixing member 36 while performing only the function of supporting the inner frame 60 and the outer frame 70 Do. In the present embodiment, the supporter 38 is formed of a separate member, but may be formed integrally with the inner frame 60 or the outer frame 70, unlike the present embodiment.

The gasket module 50 includes an insertion gasket 52 sandwiched between the glass 22 and the outer frame 70 and the glass 22 and 24 and the inner frame 60 (Not shown).

The insertion gasket 52 serves to prevent moisture and air from penetrating from the outside of the glass greenhouse. In this embodiment, a plurality of connected gasses are interrupted by one insertion gasket 52.

That is, when forming a roof or a side wall, a glass greenhouse necessarily forms a single surface by opening a plurality of glasses. In order to seal a gap between the glass and the glass, a plurality of gaskets Thereby sealing the gap. However, the inserting gasket 52 according to the present embodiment is formed to have a length long enough to cover the roof length of the glass greenhouse, and then the inserting gasket 52 is pushed into between the glass 22, 24 and the outer frame 70 No gasket seams are generated.

Further, since the conventional gasket is pressed and pressed in a direction perpendicular to the plane of the glass in a state of being fixed to the frame, it is impossible to install one gasket in a frame to which a plurality of gaskets are connected. However, since the insertion gasket 52 according to the present embodiment is inserted and assembled between the glass 22 and 24 and the outer frame 70 after the outer frame 70 is installed, a plurality of outer frames 70 are connected and installed It is possible to complete the installation with only one insertion gasket 52.

When the inner and outer sides are sealed with only one gasket, seams are not formed and the water infiltration and sealing efficiency are significantly improved.

The insertion gasket 52 includes an insertion gasket body 52a disposed between the glass 22 and the outer frame 70 and an insertion gasket body 52a integrally formed with the insertion gasket body 52a, A contact portion 52c formed in the insertion gasket body 52a and brought into close contact with the glass 22 and 24 and a contact portion 52c formed in the contact portion 52c and formed in a direction opposite to the inserting direction And a retracting prevention portion 52c formed to extend from the insertion gasket 52 to increase the frictional resistance when the insertion gasket 52 is retracted.

The insertion gasket 52 elastically supports a load applied from the outer frame 70 through the elasticity of the material and elastically supports the glass 22 and 24 and the outer frame 70 .

The insertion fitting portion 52b protrudes toward the outer frame 70 from the insertion gasket body 52a and is inserted and fixed in the gasket groove 75a in this embodiment.

Therefore, the insertion fitting portion 52b is inserted into the gasket groove 75a and fixed in the process of pushing the insertion gasket body 52a between the glass 22 and the glass 24. As described above, the insertion gasket 52 according to the present embodiment has an advantage that it can be installed between the glass 22 (24) and the outer frame 70 even after the outer frame 70 is installed, high. In particular, the insertion gasket 52 can be installed in a state of being fixed to the outer frame 70.

Further, the insertion fitting portion 52b is formed to be inclined toward the outer frame 70 so that it can be easily inserted and fixed.

Therefore, even if a plurality of glasses 22 and 24 are connected in a planar manner, the glass greenhouse according to the present embodiment can complete the sealing through one insertion gasket 52, ) Is used, there is an effect that the seam is not generated, and the moisture and the room where the air permeates are originally cut off.

The fitting gasket 54 is disposed between the glass 22 and the inner frame 60 and has a condensation guide groove 55 for guiding condensation generated inside the greenhouse.

The fitting gasket 54 is inserted and fixed into the gasket groove 65a of the inner frame 60 and the fitting gasket body 54a disposed between the glass 22 and the inner frame 60, A contact portion 54c formed in the fitting gasket body 54a and brought into close contact with the glass 22 and 24 and a contact portion 54c extending from the fitting gasket body 54a, And a condensation guide groove 55 for providing condensation.

The fitting gasket 54 seals the space between the inner frame 60 and the glass 22, 24 while supporting the inner frame 60 by the elasticity of the material like the insertion gasket 52.

The interference fit portion 54b is formed to protrude downward in the present embodiment, and is inserted and fixed in the gasket groove 65a.

The contact portion 54c contacts the glass 22 (24) to generate a frictional force.

The condensation guide groove 55 is formed in a groove shape elongated in the longitudinal direction to discharge condensation to the outside, and one side of the condensation guide groove 55 is in close contact with the fixed-portion recombination portion 66 in this embodiment. Further, the condensation guide groove 55 is disposed inside the inner frame 60 and the fitting gasket 54 to prevent condensation from leaking to the outside.

In particular, the gasket fixing portion 38c described above fixes the condensation guide groove 55 to the supporter 38, thereby suppressing the flow of the condensation guide groove 55 and maintaining the fixed state.

1 to 5, the flat sealing unit 100 may connect a plurality of glasses while blocking moisture or air from penetrating through the plurality of glasses 22 and 24. Therefore, the flat sealing unit 100 is installed in close contact with the left and right sides of the ridge 310 to form a roof 1.

Here, the ridge gasket 315 may be provided as a single member without being disconnected from the plurality of glass 22, 24 connected thereto, thereby minimizing the space in which moisture or air can be plunged into the interior.

The window unit 200 includes a window frame 210 which is coupled to the rotation hooking portions 322 provided on the left and right sides of the upper frame body 320 and a window And a flat sealing unit 100 installed on each of the window frames 210 and shielding the window 5 of the roof 1.

The window frame 210 includes a window hanging part 212 coupled to the rotation hook part 322 in the form of a hook, a flat contact part 214 in close contact with the upper surface of the plane closing unit 100, A cover engaging portion 216 to which the window cover 220 is coupled is formed.

The window hangers 212 are formed in the shape of a "J"

The flat contact portion 214 is configured to press the upper side of the flat sealing unit 100 and press the upper flat sealing portion 214 in this embodiment, .

The cover coupling part 216 is formed in a groove shape into which the end side of the window cover 220 is inserted and the end side of the window cover 220 is inserted into the cover coupling part 216 formed on each of the right and left sides, Thereby shielding the space between the window frames 210.

The window cover 220 is made of a material capable of elastic deformation so as to be deformed corresponding to the rotation angle of the window unit 200 when the window unit 200 rotates.

The window cover 220 includes a cover inserting portion 226 inserted into the cover inserting portion 216 and a shielding film 227 extending from the cover inserting portion 226 to shield the cover inserting portion 216 .

Meanwhile, the window frame 210 is rotated about the rotation hook 322, and a rotation gasket 215 is installed to prevent water from penetrating into the upper frame body 320.

The rotation gasket 215 connects between the upper frame body 320 and the window frame 210 and moves along the rotation of the window unit 200 to move the upper frame body 320 and the window frame 210 210, respectively.

6 or 7, the flat sealing unit 100 constituting the roof 1 is cut to form the window 5 in order to form the window 5 formed on the roof 1.

Even if the window unit 200 is rotated and closed on the cut flat sealing unit 100, a clearance is inevitably generated between the window unit 200 and the flat sealing unit 100 of the roof 1, Condensation and heat loss are generated.

In order to prevent this, an end frame 360 is provided on the end side of the cut flat sealing unit 100.

The end frame 360 is in close contact with the cut surface of the flat sealing unit 100 forming the window and includes a heat insulating member 366 which is in close contact with the glass 22 or 24 of the flat sealing unit 100, An upper frame 370 which is fixed on the upper side of the heat insulating member 366 and in which the window unit 200 is closely contacted and a lower frame 352 which is fixed to the lower side of the heat insulating member 366 and surrounds the lower side of the cut flat sealing unit 100 And a lower frame 380.

The heat insulating member 366 is made of a polyamide material to more effectively insulate the temperature difference between the inside and outside of the glass greenhouse.

The upper frame 370 includes a flat surface portion 372 that is in close contact with the upper surface of the flat sealing unit 100 and a vertical portion 374 that is in close contact with the cutting surface of the flat sealing unit 100, And a coupling groove 375 is formed in the portion 372.

A cushion pad 376 for buffering an impact of the window unit 200 is disposed on the flat surface portion 372. The cushion pad 376 blocks air communication when the window unit 200 is closed Respectively.

The buffer pad 376 is formed of an elastic material and is formed by protruding an elastic support portion 376a for elastically supporting the window unit 200. [

And a pad fixing portion 377 inserted and fixed in the coupling groove 375 is formed.

The lower frame 380 is formed to surround the cut surface and the lower surface of the planar sealing unit 100.

A window closing frame 290 closing a side surface of the flat sealing module 100 constituting the window unit 200 is installed at an outer edge of the window unit 200.

The window closing frame 290 is fixed in close contact with the glass of the flat sealing unit 100 and a window blocking member 292 is provided to contact the buffer pad 376 when the window 5 is closed. The window blocking member 292 prevents the inflow of air into the window 5 together with the buffer pads 292, and minimizes the occurrence of condensation due to the temperature difference between the indoor and outdoor through the heat insulation.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. It will be possible.

10: roof support frame 15: side wall support frame
15a: side wall discharge hole 16: load supporting portion
17: cover supporting portion 22: glass
30: Fixed module 38: Supporter
50: gasket module 52: insertion gasket
54: insertion gasket 60: inner frame
61: bolt 62: inner frame body
63: nut 64: bolt insertion portion
65: Gasket fixing part 66: Fixing part Reassembling part
70: outer frame 72: outer body
74: groove 75: gasket fixing part
90: eaves sealing module 91: eaves body
92: eave cover 95: eaves gasket
98: eave supporting member 100: flat sealing unit
200: window unit 210: window frame
220: window cover 290: window closing frame
300: roof unit 310: ridge
320: upper frame body 330: lower frame body
360: End frame 370: Upper frame
380: Lower frame

Claims (5)

A ridge coupling structure of a glass greenhouse in which a roof (1) is formed such that a ridge (310) is disposed and a window (5)
A roof unit 300 having a roof 1 including a flat sealing unit 100 formed with the ridges 310 and formed by connecting a plurality of glasses 22 and 24;
And a window unit (200) coupled to the roof unit (300) and opening / closing a part of the roof (1) while rotating at a predetermined angle,
The roof unit (300)
A crest 310 fixed to the main frame 10 supporting a load of the glasshouse; Closely coupled to the ridge 330, the ridge coupling structure of the glass greenhouse comprising a plane sealing unit 100 formed by connecting a plurality of glass 22, 24.
The method according to claim 1,
The ridge 310
An upper frame body 320 to which the window unit 200 is coupled;
A lower frame body 330 coupled to the upper frame body 320 and secured to the main frame 10 supporting the glasshouse;
A ridge coupling structure of a glass greenhouse comprising a heat insulating member 316 disposed between the upper frame body 320 and the lower frame body 330 to insulate the inside and the outside.
The method according to claim 2,
The upper frame body 320 is fixed to the lower frame body 330 side, the ridge coupling structure of the glass greenhouse formed with a rotating hook portion 322 for the relative rotation with the window unit 200.
The method according to claim 3,
The window unit (200)
A window frame 210 coupled to each of the rotation hooks 322 provided on the right and left sides of the upper frame body 320 and rotated;
A window cover 220 for shielding the respective window frames 210 by connecting them;
And the flat sealing unit (100) installed on each of the window frames (210) and shielding the window (5) of the roof (1).
The method of claim 4,
The window frame (210)
A window hanging part 212 which is coupled to the rotation hanging part 322 in a hooked manner and rotated;
A flat contact portion 214 which is in close contact with an upper surface of the flat sealing unit 100 of the roof unit 100;
And a cover engaging portion (216) to which the window cover (220) is coupled.

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