JP2019526729A - Elevated split joinery with watertight optimization structure - Google Patents

Abstract

The present invention can improve the assembly strength and flooding performance of the horizontal bar that divides the opening of the window frame frame vertically, and natural drainage is easy by applying a stepped drainage structure to the lower part of the window frame frame. The present invention relates to an upright split joinery to which the watertight optimization structure is applied. To achieve this, the present invention includes: a window frame frame 100; and an inner facing surface of the window frame frame 100 so that the outdoor opening of the window frame frame 100 can be partitioned into an upper opening S1 and a lower opening S2. A horizontal bar 110 coupled to the interior of the window frame frame 100 by at least a pair of indoor shojis 210 slidably opened and closed; the upper opening S1 and the lower opening S2 And an outdoor shoji 220 coupled to each other.

Description

  More specifically, the present invention relates to a vertical partition, and more specifically, it is possible to improve the assembly strength and flooding performance of a horizontal bar that divides an opening of a window frame frame vertically, and natural drainage is provided at a lower portion of the window frame frame. The present invention relates to an upright split joinery to which a watertight optimization structure using an easy drainage structure is applied.

  In recent years, buildings such as condominiums and Sumisho complex buildings tend to be taller, and as a result, a considerably large external wind pressure acts on the fittings provided in the buildings. Therefore, a high-rise building is required to have a fitting with excellent watertightness as well as strength enough to withstand external wind pressure.

  In order to provide structural stability, the joinery may be provided with an elevational split structure including a horizontal bar and a vertical bar.

  Conventionally, a joint application having such an elevational split structure has been previously filed as Korean Patent No. 10-2014-0054571 (publication date: 2014.05.09).

  Specifically, as shown in FIG. 1, the horizontal split joiner 1 uses the horizontal bar 3. The part where the horizontal bar 3 and the window frame 2 are joined is required to have a high degree of watertightness.

  In this case, the portion where the horizontal bar 3 and the window frame 2 are joined is generally welded. However, in this case, sufficient water-repelling performance cannot be ensured, so that water tightness may be a problem.

形状の組立具４を媒介として窓枠２に結合する構造が提案されている。 In order to prevent this and to allow the horizontal bar 3 to be firmly assembled,

There has been proposed a structure that is coupled to the window frame 2 through a shaped assembly 4 as a medium.

  However, the assembly tool 4 as described above has a simple structure. In particular, due to the structure of the window frame, the assembly tool 4 is applied to a part of the horizontal bar 3 to reduce the assembly strength. There's a problem.

  On the other hand, in the case of coastal joinery, watertightness is required by occasional occurrence of rainwater or seawater scattered by rough waves in the window frame 2 during a typhoon or rainy weather.

  As a structure for improving such watertight performance, the conventional window frame 2 is provided with a drain hole. Most of the drainage holes are usually opened horizontally in the lower part of the window frame 2.

  However, the window frame 2 having the above-described structure can discharge the water to the outside through the drainage hole when a small amount of water flows from the outside, but a certain amount of water is pushed at a time. In this case, it is difficult to endure only with the drainage capacity of the drainage hole. Therefore, there is a problem that water that could not be drained to the outdoor side flows into the room through a gap between the rails on the indoor side.

  The present invention has been devised to solve the above-described problems, and can improve the assembly strength and flooding performance of the horizontal bar that divides the opening of the window frame frame vertically. Its purpose is to provide an elevational split joinery to which a watertight optimization structure that facilitates natural drainage by applying a stepped drainage structure at the bottom.

  An elevational split joinery to which the watertight optimization structure according to the present invention for realizing the object as described above is applied is a window frame frame; an outdoor opening of the window frame frame is divided into an upper opening and a lower opening. A horizontal bar coupled to the inner facing surface of the window frame frame through an assembly tool; at least a pair of indoor side doors slidably coupled to an indoor side opening of the window frame frame; and the upper side An outdoor shoji coupled to the opening and the lower opening, respectively.

  In the present invention having the above-described configuration, the assembly strength can be increased by connecting the horizontal bars that divide the outdoor opening of the window frame frame up and down with a high-strength integrated assembly as a medium.

  Further, by forming a flooded wall for providing a flooded space on the upper surface of the horizontal bar and forming the indoor side wall higher than the outdoor side wall, the water stored in the flooded space overflows indoors. Can be prevented, thereby improving the flooding performance.

  Further, there is an advantage that natural drainage can be facilitated by applying a stepped drainage structure to the lower part of the window frame.

It is a principal part disassembled perspective view which shows the coupling | bonding structure of the horizontal bar of the conventional vertical surface division | segmentation joinery. It is an indoor side elevational view of an elevation surface split joinery to which a watertight optimization structure according to the present invention is applied. It is sectional drawing which follows the II line | wire of FIG. It is a sectional side view of the window frame frame which concerns on this invention. It is side sectional drawing of the horizontal bar which concerns on this invention. It is a perspective view of the assembly tool which concerns on this invention. It is a disassembled perspective view which shows the combined state of the assembly tool which concerns on this invention. It is a figure which shows the state by which the assembly tool which concerns on this invention was couple | bonded with the edge part of a horizontal bar.

  Hereinafter, a configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

  Here, in adding reference numerals to the components of each drawing, only the same components are represented by the same symbols as much as possible even if they are displayed on other drawings. You have to be careful.

  FIG. 2 is an indoor side elevational view of an upright split joinery to which the watertight optimization structure according to the present invention is applied, FIG. 3 is a cross-sectional view taken along line II of FIG. 2, and FIG. FIG. 5 is a side sectional view of a window frame according to the present invention, and FIG. 5 is a side sectional view of a horizontal bar according to the present invention.

  Referring to FIGS. 2 and 3, an upright split joinery to which a watertight optimization structure according to a preferred embodiment of the present invention is applied includes a window frame frame 100, and an outdoor opening of the window frame frame 100 as an upper opening S <b> 1. The horizontal bar 110 is coupled to the inner facing surface of the window frame frame 100 with the assembly tool 120 as a medium, and is slidably coupled to the indoor opening of the window frame frame 100 so as to be slidable. A pair of indoor shojis 210 and an outdoor shoji 220 coupled to the upper opening S1 and the lower opening S2, respectively.

  The configuration of the present invention will be specifically described as follows.

  First, the window frame 100 is formed such that the lower inner peripheral surface is inclined downward toward the outdoor side, and the outdoor side is formed lower than the indoor side, whereby a stepped drainage structure is applied. The

  In other words, as shown in FIG. 4, the window frame frame 100 is formed with a stepped drainage structure, thereby preventing water that has flowed into the window frame frame 100 from the outside from flowing into the indoor side. be able to. The inflowing water is naturally drained to the outside through a plurality of drain holes (not shown) penetrating through the indoor rail 101 and the outdoor rail 103.

  A cover profile 130 may be coupled to the flooded space between the indoor rail 101 and the outdoor rail 103 of the window frame 100 so as to conceal the situation of the water pool due to drainage delay.

  In this case, the cover profile 130 is formed in a “U” shape with an opening at the bottom, and a plurality of drain holes (not shown) are formed at the bottom so that water accumulated in the flooded space can be drained to the outside. Can be formed.

  In addition, the cover profile 130 is provided with a locking step 131 so that both sides can be fitted and fixed with a snap-fit structure in the flooded space, whereby the cover profile 130 is arbitrarily removed. This can be prevented.

  Referring to FIG. 3 again, the outdoor shoji 220 is composed of at least a pair of first shoji 221 that is slidably coupled to the upper opening S1 and a second shoji 223 that is fixedly coupled to the lower opening S2. The Of course, the present invention is not limited to this, and the sliding window and the fixed window can be arbitrarily changed and applied according to the user's preference.

  Referring to FIG. 5, the upper surface of the horizontal bar 110 is formed with a rail 111 provided so that the first shoji 221 can be slidably opened and closed, and spaced apart from the inside / outside of the rail 111. And a flooded wall 113 for providing a flooded space.

  The flood wall 113 is formed such that the indoor side wall 113a is higher than the outdoor side wall 113b. That is, by increasing the height of the rail 111 and the flooded wall 113 as compared with the prior art, it is possible to improve the flooding capacity of the horizontal bar 110, thereby allowing the water stored in the flooded space to enter the indoor side. It is possible to prevent overflow. Specifically, the height (h) of the indoor side wall 113a may be 38 to 42 mm, preferably 40 mm (conventionally formed with 35 mm conventionally) from the upper surface of the horizontal bar 110.

  6 to 8, the horizontal bar 110 having the above-described structure is coupled and fixed to the window frame 100 through the assembly tool 120. Such an assembly tool 120 may be formed of a metal material.

  Specifically, the assembly tool 120 includes a first fixing part 121 that is fixed to the inner peripheral surface of the window frame frame 100 with a fastening member as a medium, and one surface of the first fixing part 121 that protrudes in the horizontal direction. The end portion of the horizontal bar 110 is configured to include a second fixing portion 123 that is fitted to the upper surface and the bottom surface and is fixed with a fastening member as a medium.

  In this case, the first fixing portion 121 is provided with a first coupling groove 121a so that a protrusion 105 (see FIG. 7) provided on the window frame 100 can be mounted. That is, by allowing the assembly tool 120 to be easily installed on the facing surface of the window frame frame 100 provided with the protrusions 105, the assembly tool 120 can be firmly coupled as compared with the conventional case. The assembly strength of the horizontal bar 110 can be improved.

  And, similarly to the first fixing portion 121, the second fixing portion 123 can be fitted between the rail 111 on the top surface of the horizontal bar 110 and the structure on the bottom surface of the horizontal bar 110 (see FIG. 8). As described above, the second coupling groove 123a is provided in a corresponding shape. As a result, the second fixing portion 123 can also be firmly coupled.

  In the vertical split joinery to which the watertight optimization structure according to the present invention configured as described above is applied, the horizontal bar 110 that divides the outdoor opening of the window frame frame 100 up and down is replaced with a high strength integrated assembly tool 120. By combining as a medium, the assembly strength can be increased.

  Further, by forming a flooded wall 113 for providing a flooded space on the upper surface of the horizontal bar 110 and forming the indoor side wall 113a higher than the outdoor side wall 113b, the water stored in the flooded space overflows indoors. This can be prevented, thereby improving the flooding performance.

  Moreover, natural drainage can be facilitated by applying a stepped drainage structure to the lower part of the window frame 100.

  While the present invention has been illustrated and described with reference to specific preferred embodiments, the present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the spirit of the present invention. Of course, it is possible.

DESCRIPTION OF SYMBOLS 100 Window frame frame 101 Indoor side rail 103 Outdoor side rail 105 Protrusion part 110 Horizontal bar 111 Rail 113 Flooding wall 113a Indoor side wall 113b Outdoor side wall 120 Assembly tool 121 1st fixing | fixed part 121a 1st coupling groove 123 2nd fixing | fixed part 123a 1st 2 coupling groove 130 cover profile 131 locking step part 210 indoor shoji 220 outdoor shoji 221 first shoji 223 second shoji

Claims (10)

Window frame (100);
An assembly tool (120) is interposed on the inner facing surface of the window frame frame (100) so that the outdoor opening of the window frame frame (100) can be divided into an upper opening (S1) and a lower opening (S2). A horizontal bar (110) coupled as
At least a pair of indoor shojis (210) slidably coupled to the indoor openings of the window frame frame (100);
An outdoor shoji (220) respectively coupled to the upper opening (S1) and the lower opening (S2);
Elevated split joinery including. The window frame (100)
The lower inner peripheral surface is formed so as to incline downward toward the outdoor side, and further includes a stepped drainage structure applied by forming the outdoor side lower than the indoor side. The elevation division | segmentation joinery of 1. In the flooded space between the indoor rail (101) and the outdoor rail (103) of the window frame frame (100),
The elevational split joinery according to claim 1, further comprising a 'U'-shaped cover profile (130) opened at a lower side so as to conceal a situation of a puddle caused by drainage delay. The cover profile (130) is
The elevation division | segmentation joinery of Claim 3 further provided with the latching step part (131) so that both sides could be engage | inserted and fixed by the snap fit (snap-fit) structure in the said flooded space. The outdoor shoji (220)
At least a pair of first shojis (221) coupled to the upper opening (S1) so as to be slidable;
2. The vertical split joinery according to claim 1, comprising a second shoji (223) fixedly coupled to the lower opening (S <b> 2). On the upper surface of the horizontal bar (110),
A rail (111) provided so that the first shoji (221) can be slidably coupled;
The standing wall according to claim 5, further comprising: a flooded wall (113) that is formed to be separated into the interior / outside of the rail (111) to provide a flooded space therebetween. Surface split joinery. The flood wall (113) is
Elevated-part split joinery according to claim 6, characterized in that the indoor side wall (113a) is formed higher than the outdoor side wall (113b). The assembly tool (120)
A first fixing part (121) fixed to an inner peripheral surface of the window frame frame (100) through a fastening member;
A second fixing portion that is formed to protrude in a horizontal direction on one surface of the first fixing portion (121), is fitted to the upper surface and the bottom surface of the end portion of the horizontal bar (110), and is fixed through a fastening member. (123), The elevation division | segmentation joinery of Claim 1 characterized by the above-mentioned. In the first fixing part (121),
The vertical surface split joinery according to claim 8, further comprising a first coupling groove (121a) so that a protrusion (105) provided on the window frame frame (100) can be mounted. In the second fixing part (123),
And further comprising a second coupling groove (123a) so as to fit between a rail (111) on the top surface of the horizontal bar (110) and a structure on the bottom surface of the horizontal bar (110). Item 10. The vertical split joinery according to item 8.

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