KR200183379Y1 - Sliding window or door with high and low positioned drain holes - Google Patents

Abstract

The present invention is a lower window frame in the microscopic window (or door) made of a synthetic resin material

The watertightness is improved by changing the internal structure of the door frame to form a water collecting groove and draining the drain hole up and down to allow drainage by a drop method using a position difference. To a finer window (or door).

After the water flows in from the outside, it flows into the drain hole opened beneath the windshield between the inner and outer rails of the lower window frame or the drain hole opened in the lower window frame directly facing the outside between the inner and outer rails of the lower window frame. By the final drainage through the collecting groove into the side drain hole of the lower window frame, the drainage capacity is significantly improved compared to the drain hole that was conventionally opened horizontally on the outer rail of the lower window frame.

That is, the amount of water drained is larger than the amount of water that is drained due to the dropping method due to the difference in the position of the drain hole, so that the water does not overflow to the inside, thereby improving watertight performance.

Description

Sliding Window or Door with High and Low Positioned Drain Holes}

The present invention is a lower window frame in the microscopic window (or door) made of a synthetic resin material

(Or the internal structure of the door frame) to form a collecting groove, the opening position of the drain hole up and down to drain the water by the free fall method using the position difference. It relates to an improved microscopic window (or door).

The description of the following statement is the same as that of the window, so it is omitted.

In general, the drainage hole of the conventional microscopic window was mostly opened in the horizontal direction on the outer rail of the lower window frame.

Looking at the drain hole of such a conventional microscopic window through Figures 1 to 3 as follows.

1 is a front view of a conventional micromachined window, which shows that the micromachined window is largely composed of a window pair 1, an upper window frame 2, a side window frame 3, and a lower window frame 4.

FIG. 2 is a cross-sectional view taken along the line AA of FIG. 1, with a lower window frame 4 having a window 1, an inner rail 9 and an outer rail 10, a windshield 5 in contact with the lower window frame 4, and a lower portion. The bottom of the microscopic window with the drain hole 6 which is open in the horizontal direction on the outer rail 10 of the window frame 4 is shown.

3 is a perspective view of the windshield 5, in which the end 13 of the bottom of the windshield 5 is cut out, and it can be seen that several wings are in the vertical direction.

When the windshield 5 closes the window, the material is made of contact with the upper window frame 2 and the lower window frame 4 where the upper and lower portions of the center conduit where the window 1 and the window 1 overlap each other meet. Because it is a flexible vinyl chloride resin, it is flexible and when the window is closed, the wing part of the windshield 5 bends and the upper window frame 2, the window frame 1, the lower window frame 4 and Sealing between the window (1), and acts as an airtight material (氣密 材) to prevent the wind flowing from the outside to the inside of the window.

In addition, the condensation water generated inside the window due to the condensation phenomenon caused by the temperature difference between the indoor and outdoor and the role of blocking the water falling into the lower window frame 4 from the outside into the inside of the windshield (5) It also serves to drain to the outside through the bottom end (13).

The drain hole 6 of the conventional microscopic window is opened in the horizontal direction in the outer rail 10 of the lower window frame 4, so that the drainage is not good in a high wind pressure area such as a coastal area or a high-rise building. There was this.

In addition, there is a windshield (5), although it prevents the water falling into the lower window frame (4) from the outside into the inside, it was impossible to completely block the flow of water, and also through the windshield (5) Although the water introduced into the water was drained at a low speed through the end 13 of the bottom of the windshield 5, in the case of heavy rain, the water introduced into the water is not drained by the water pressure accumulated in the outside. There was often a problem that the water overflows the inner rail 9 of the lower window frame 4 to the inside.

In this invention, by changing the internal structure of the lower window frame to form a collecting groove by a separate rib (Rib) inside the window frame, by opening the drain hole up and down to drain by the drop method using the position difference, To provide a microscopic window with improved watertightness.

1 is a front view of a conventional microscopic window.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a perspective view of a windshield;

Figure 4 is a front view of the microscopic window according to the present invention.

5 is a cross-sectional view taken along the line B-B in FIG.

6 is a cross-sectional view taken along the line C-C of FIG.

(Explanation of symbols for the main parts of the drawing)

1: window frame 2: upper window frame

3: side window frame 4: lower window frame

4 ': lower window frame 5: windshield

6: drain hole 7: drain hole

7 ': drain hole 8: drain hole

9: inner rail 10: outer rail

11: rib 12: catchment groove

13: end of the bottom of the windshield

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

4 is a front view of the micromachined window according to the present invention, and shows that the micromachined window is largely composed of a window pair 1, an upper window frame 2, a side window frame 3, and a lower window frame 4 ′.

FIG. 5 is a cross-sectional view taken along the line BB of FIG. 4 with a separate rib 11 inside the lower window frame 4 ′ with the window 1, the inner rail 9 and the outer rail 10, and the lower window frame 4 ′. Winding plate (5) contacting between the inner rail (9) and the outer rail (10) of the lower window frame (4 ') to the overlapping groove (12), the window (1) and the window (1) formed by , Shows a lower part of the micromachined window consisting of a drainage hole 7 opened below the windshield 5 and a drainage hole 8 opened on the side of the lower window frame 4 ′.

That is, in order to block the water pouring into the lower window frame 4 'from entering through the windshield 5, a drain hole 7 is opened below the windshield 5, and the water flowing into the drain hole 7 is lowered. After being introduced into the collecting groove 12 in the window frame 4 ', the drainage hole 8 on the side of the lower window frame 4' is to be the final drainage.

FIG. 6 is a cross-sectional view taken along the line CC of FIG. 4, with a separate rib 11 inside the lower window frame 4 ′ with the window 1, the inner rail 9 and the outer rail 10, and the lower window frame 4 ′. The water collecting groove 12 formed by the slit, the drainage hole 7 'and the lower window frame 4' opened in the lower window frame 4 'between the inner rail 9 and the outer rail 10 of the lower window frame 4'. ) Shows the lower part of the micromachined window consisting of a drain hole 8 opened at the side.

That is, not only below the windshield 5, but also in the lower window frame 4 ′ between the inner rail 9 and the outer rail 10 of the lower window frame 4 ′, which is full of water and directly faces the outside air. ') Was opened, the water introduced into the drain hole (7') is to be introduced into the collecting groove 12, and then to the final drain to the drain hole (8) of the side of the lower window frame (4 ').

The microscopic window of the present invention allows the drainage to be drained by a drop-off method by moving the drain hole up and down, and even when the amount of the drained water is larger than the amount of the drained water, the water never overflows inside the window. Its purpose is to improve abilities.

The effects of the present invention are as follows.

The water flowing in from the outside flows into the drainage hole 7 or the inner window of the lower window frame 4 'opened beneath the windshield 5 between the inner rail 9 and the outer rail 10 of the lower window frame 4' ( 9) flows into the drainage hole 7 'opened in the lower window frame 4' directly facing the outside air between the outer rail 10 and the side drain hole of the lower window frame 4 'through the collecting groove 12. By finally draining to (8), the drainage capacity was greatly improved compared with the drain hole 6 which was conventionally opened horizontally in the outer rail 10 of the lower window frame 4 '.

That is, the amount of water drained is larger than the amount of water due to the dropping method due to the difference in the position of the drain hole, so that the water does not overflow to the inside, thereby improving the watertight performance.

Claims (1)

Separate ribs inside the lower window frame 4 'with the window sill 1, the upper window frame 2, the side window frame 3, the inner rail 9 and the outer rail 10, and the lower window frame 4' 11, the lower window frame 4 'at the portion where the window leaf 1 and the window leaf 1 overlap between the inner rail 9 of the lower window frame 4' and the outer rail 10 formed by the catching groove 12 formed by 11). Windshield 5 in contact with the windshield, a drain hole 7 opened below the windshield 5, and a lower window frame 4 'between the inner rail 9 and the outer rail 10 of the lower window frame 4'. A microscopic window consisting of an open drain hole 7 'and a drain hole 8 opened on the side of the lower window frame 4'.