CN215213210U - Energy-conserving swinging-out casement window drainage structures - Google Patents

Abstract

The utility model discloses an energy-conserving swinging-out casement window drainage structures, including the window frame, casement and casement attach the frame. The window sash auxiliary frame is fixed on the window outer frame by adopting a post-assembly method, drain holes are formed in the bottom of the window sash in a staggered mode and used for draining water accumulated in a window sash glass groove opening, the drain holes (arranged in a staggered mode) are formed in the position, where the window sash auxiliary frame is connected with the window sash, of the groove C, and the drain holes (arranged in a staggered mode) are formed in the outdoor portion of the window outer frame and communicated with the outdoor portion. The rainwater is discharged out of the room rapidly from the window sash auxiliary frame or the window sash under the condition of large height drop and balanced air pressure. Through using the utility model discloses an energy-conserving swinging-out casement window drainage structures can effectively solve because of the untimely ponding toward indoor spilling over often of drainage, rainwater flows in and the corrosion that the long-time soaking of door and window five metals arouses, rust scheduling problem from drain hole department under the effect of wind pressure during the heavy rain.

Description

Energy-conserving swinging-out casement window drainage structures

Technical Field

The utility model belongs to building door and window field relates to a swinging-out casement window, concretely relates to energy-conserving swinging-out casement window drainage structures.

Background

The door and window is one of building structures, and the aluminium alloy window is an indispensable part in the building structure at present, and the door and window's effect is not only to make the building field of vision penetrating not only in order to increase the ventilation rate, but also is used for the sunshade sound insulation, keeps out the wind and takes shelter from the rain, makes our residence more comfortable, promotes our quality of life. The water-proof performance of doors and windows in regions with frequent precipitation in the south influences the life quality of people to a great extent, and the good door and window drainage system can greatly improve the water-proof performance of the doors and windows.

The conventional drainage system of the outwardly opened window (as shown in fig. 7) has the following disadvantages: firstly, the window sash glass groove is not provided with a drain hole, if rainwater carelessly enters from the window sash sealing rubber strip, accumulated water is easy to permeate indoors. And secondly, the drain hole can only be opened at the C groove of the window frame, the window sash is sealed with the window frame by the adhesive tape when closed, the adhesive tape is dried by wind for a long time and is hardened and shrunk, the elasticity is insufficient, a gap can be formed between the window sash and the window frame when the window sash and the window frame are closed, outdoor rainwater is poured into the room through the top of the window sash and cannot be discharged in time, and the risk of rusting and failure caused by overflowing indoors and soaking of door and window hardware exists. The problem results in that the drainage performance of the traditional aluminum alloy outward-opening window is poor, and especially in heavy rainfall in the south and the like, the user experience in multiple wind areas is poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a simple structure, can be perpendicular vertical smooth and easy drainage, can't in time discharge when preventing that the rainwater from pouring into in a large number and lead to ponding to overflow indoor and soak the door and window five metals, solve the energy-conserving swinging-out casement window drainage structures of the poor problem of traditional drainage system.

In order to realize the purpose, the technical scheme of the utility model is that: the utility model provides an energy-conserving swinging-out casement window drainage structures includes:

a window sash; a window sash drainage cavity is arranged on the outer side of the window sash, a first drainage hole is formed in the top of the window sash drainage cavity, and a second drainage hole is formed in the bottom of the window sash drainage cavity;

a sash auxiliary frame; the window sash is arranged on the window sash auxiliary frame, a window sash auxiliary frame drainage cavity is arranged on the outdoor side of the window sash auxiliary frame, a third drainage hole is formed in the top of the window sash auxiliary frame drainage cavity, and a fourth drainage hole is formed in the bottom of the window sash auxiliary frame drainage cavity;

a window outer frame; the window sash auxiliary frame is arranged on the window outer frame, a window outer frame drainage cavity is arranged on the outdoor side of the window outer frame, a fifth drainage hole is arranged on the left side of the window outer frame drainage cavity, and a sixth drainage hole is arranged on the right side of the window outer frame drainage cavity;

the first drain hole, the second drain hole, the third drain hole, the fourth drain hole and the fifth drain hole are sequentially arranged from top to bottom, the sixth drain hole is located on the outer side of the fifth drain hole, and the sixth drain hole is communicated with the outdoor space.

Furthermore, the window sash comprises a first window sash frame, a second window sash frame and a window sash frame heat insulation strip, the first window sash frame is arranged on one outdoor side, the second window sash frame is arranged on one indoor side, and the first window sash frame and the second window sash frame are connected through the window sash frame heat insulation strip.

Furthermore, the sash auxiliary frame comprises a first sash auxiliary frame, a second sash auxiliary frame and a sash auxiliary frame heat insulation strip; the first sash auxiliary frame is arranged on one outdoor side, the second sash auxiliary frame is arranged on one indoor side, and the first sash auxiliary frame and the second sash auxiliary frame are connected through the sash auxiliary frame heat insulation strip.

Furthermore, the window frame comprises a first window frame, a second window frame and a window frame heat insulation strip, wherein the first window frame is arranged on one side outdoors, the second window frame is arranged on one side indoors, and the first window frame and the second window frame are connected through the window frame heat insulation strip.

Further, of the first drain hole, the second drain hole, the third drain hole, the fourth drain hole and the fifth drain hole, the drain holes in the upper and lower adjacent directions are in a staggered layout, and the fifth drain hole and the sixth drain hole are in a staggered layout.

The utility model discloses energy-conserving swinging-out casement window drainage structures has following beneficial effect:

1. the utility model discloses energy-conserving swinging-out casement window drainage structures has solved traditional swinging-out casement window drainage system rainwater or ponding and has flowed via two wash port side directions in the window frame outside, and the tension that bottom adhesive tape compression leads to water when the casement is closed is greater than atmospheric pressure and can't in time discharge, and indoor is reversely poured into to ponding, soaks the door and window five metals and makes it rust, corrode inefficacy scheduling problem.

2. The utility model discloses wash port is seted up to energy-conserving swinging-out casement window drainage structures on a plurality of cavitys of section bar, forms atmospheric pressure balance, and water is outdoor via first wash port, second wash port, third wash port, fourth wash port, fifth wash port, sixth wash port vertical downward discharge in proper order. The problem of traditional drainage difficulty is greatly improved, the problem that the drainage is untimely, the drainage is poured into a room, and accumulated water soaks door and window hardware to cause the door and window hardware to rust and corrode and lose efficacy is solved.

Drawings

Fig. 1 is a schematic structural view of the energy-saving outward-opening window drainage structure of the utility model;

FIG. 2 is a schematic view of the outer frame of the window of FIG. 1;

FIG. 3 is a schematic view of the window sash frame of FIG. 1;

FIG. 4 is a schematic view of the sash of FIG. 1;

FIG. 5 is a schematic view of the construction of the screen window of FIG. 1;

fig. 6 is a schematic view of a drainage path of the energy-saving outward-opening window drainage structure of the present invention;

fig. 7 is a schematic structural view of a conventional outward-opening window drainage system.

In the figure: 1. a window outer frame; 101. a first window outer frame; 102. a second window outer frame; 103. a window outer frame heat insulation strip; 104. sealing rubber strips for the outer window frame; 105. a notch of the adhesive tape of the window outer frame; 106. a drainage cavity of the window outer frame; 107. a fifth drain hole; 108. a sixth drain hole; 2. a window sash; 201. glass; 202. a first drain hole; 203. a window sash drainage cavity; 204. a second drain hole; 205. a first sash frame; 206. a second sash frame; 207. a window sash frame heat insulation strip; 3. a sash auxiliary frame; 301. a first sash auxiliary frame; 302. a second sash auxiliary frame; 303. the sash attaches the frame heat insulating strip; 304. a window sash auxiliary frame adhesive tape notch; 305. a sash auxiliary frame sealing rubber strip; 306. a window sash hardware notch; 307. a screen window hardware notch; 308. a window sash auxiliary frame drainage cavity; 309. a third drain hole; 310. a fourth drain hole; 4. a screen window sash; 5. a conventional window casing; 6. a conventional window sash; 7. sealing rubber strips; 8. and (4) draining the water.

Detailed Description

For the purpose of explaining the technical content and the structural features of the energy-saving outward-opening window drainage structure of the present invention in detail, the following description is further made with reference to the accompanying drawings in combination with the embodiments.

As shown in fig. 1, 2, 3, 4, 5 and 6, the utility model discloses energy-saving outward-opening window drainage structure, including casement 2, casement auxiliary frame 3, window frame 1 and screen window fan 4.

As shown in fig. 2, the window frame 1 includes a first window frame 101, a second window frame 102, a window frame heat insulation strip 103 and a window frame sealing rubber strip 104, the window frame heat insulation strip 103 is used for connecting the first window frame 101 and the second window frame 102 to form a window frame profile, the first window frame 101 is arranged at the outdoor side, the second window frame 102 is arranged at the indoor side, the window frame profile is assembled into a whole window frame through a frame assembling corner connector in a factory, and the window frame sealing rubber strip 104 is pressed into a window frame rubber strip notch 105. A window frame drainage cavity 106 is arranged on the outdoor side of a first window frame 101 of the window frame 1, a fifth drainage hole 107 is arranged on the left side of the window frame drainage cavity 106 (the inner side cavity wall of the small cavity of the outdoor end section bar of the window frame), and a sixth drainage hole 108 is arranged on the right side of the window frame drainage cavity 106 (the outer side cavity wall of the small cavity of the outdoor end section bar of the window frame); the number of the fifth drain holes 107 and the sixth drain holes 108 is plural, and the left and right rows of drain holes are arranged in a staggered manner. The sixth drain hole 108 communicates with the outside of the room.

As shown in fig. 3, the sash auxiliary frame 3 includes a first sash auxiliary frame 301, a second sash auxiliary frame 302, a sash auxiliary frame heat insulation strip 303, and a sash auxiliary frame sealing rubber strip 305, wherein the first sash auxiliary frame 301 is provided with a sash hardware notch 306, and the second sash auxiliary frame 302 is provided with a screen hardware notch 307; the sash attaches frame insulated strip 303 and is used for connecting first sash and attaches frame 301 and second sash and attaches frame 302, and first sash attaches the frame and sets up in the outdoor side, and second sash attaches frame 302 and sets up in the indoor side, forms the sash through group frame angle sign indicating number equipment and attaches the frame framework in the mill, and further attaches frame joint strip 305 with the sash and impresses in the sash attaches frame joint strip notch 304, and this moment whole processing of whole sash attaches the frame and accomplishes. A sash auxiliary frame drainage cavity 308 is arranged on the outdoor side of the first sash auxiliary frame 301, a third drainage hole 309 is arranged at the top of the sash auxiliary frame drainage cavity 308, and a fourth drainage hole 310 is arranged at the bottom of the sash auxiliary frame drainage cavity 308; the number of the third drain holes 309 and the fourth drain holes 310 is plural, and the third drain holes and the fourth drain holes are arranged in a vertically staggered manner. The sash accessory frame drainage cavity 308 is positioned below the C groove (sash hardware notch 306) where the sash accessory frame 3 is connected with the sash 2.

As shown in fig. 4, the window sash 2 includes a first sash frame 205, a second sash frame 206, a sash frame insulating strip 207, and glass 201. The window sash frame heat insulation strip 207 is used for connecting a first window sash frame 205 and a second window sash frame 206 to form a window sash frame section, the first window sash frame 205 is arranged on the outdoor side, the second window sash frame 206 is arranged on the indoor side, and a window sash frame body is formed in a factory through frame assembly corner connectors. The outdoor side of the first window sash frame 205 is provided with a window sash drainage cavity 203, the top of the window sash drainage cavity 203 is provided with a first drainage hole 202, and the bottom of the window sash drainage cavity 203 is provided with a second drainage hole 204. The window sash drain chamber 203, the first drain hole 202 and the second drain hole 204 are used for draining the window sash 2 glass slot opening.

Casement 2 passes through the window hardware installation in mill and attaches frame 3 and form whole back at the casement and install on window frame 1 through stainless steel screw indoor can be quick, reduces the direct maloperation, the danger that the casement dropped, the cost of using manpower sparingly of casement 2 when the job site and window frame 1 are outdoor installation.

The first drain hole, the second drain hole, the third drain hole, the fourth drain hole and the fifth drain hole are sequentially arranged from top to bottom, and the sixth drain hole is located on the outer side of the fifth drain hole. The water discharge holes are in a step shape, so that air pressure balance is formed, and accumulated water in the cavity can be discharged in time if water is carelessly in the cavity. The three-stage stepped drain holes are arranged in a staggered mode, the sash auxiliary frame 3 and the sash 2 are arranged on the indoor side and provided with sash auxiliary frame sealing rubber strips 305, and rainwater in storm weather can be effectively prevented from flowing into the indoor space through the drain holes in the cavity of the profile under the action of wind pressure.

The utility model discloses energy-conserving swinging-out casement window drainage structures, rainwater or ponding are through first wash port 202 → second wash port 204 → third wash port 309 → fourth wash port 310 → fifth wash port 107 → sixth wash port 108 perpendicular downward formation drainage channel in proper order and are discharged outdoors, owing to there are casement drainage chamber, casement attach frame drainage chamber, the three cascaded drainage cavity in window frame drainage chamber, the high drop is big, has the balanced effect of atmospheric pressure, and the drainage effect obviously promotes. And because the drain holes are all arranged in a staggered way, in the storm weather, strong wind can not carry rainwater to enter the cavity through the drain holes and flow into the room. Sealing rubber strips are arranged inside and outside the window sash auxiliary frame 3 and the window sash 2, and further a safety is added for ensuring that rainwater overflows into the room.

As shown in fig. 7, the drainage system of the conventional outward opening window is shown, where 5 is a conventional window frame, 6 is a conventional window sash, 7 is a sealing rubber strip, and 8 is a drainage hole.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the scope of the invention, therefore, the present invention is not limited by the appended claims.

Claims (5)

1. The utility model provides an energy-conserving swinging-out casement window drainage structures which characterized in that includes:

a window sash; a window sash drainage cavity is arranged on the outer side of the window sash, a first drainage hole is formed in the top of the window sash drainage cavity, and a second drainage hole is formed in the bottom of the window sash drainage cavity;

a sash auxiliary frame; the window sash is arranged on the window sash auxiliary frame, a window sash auxiliary frame drainage cavity is arranged on the outdoor side of the window sash auxiliary frame, a third drainage hole is formed in the top of the window sash auxiliary frame drainage cavity, and a fourth drainage hole is formed in the bottom of the window sash auxiliary frame drainage cavity;

a window outer frame; the window sash auxiliary frame is arranged on the window outer frame, a window outer frame drainage cavity is arranged on the outdoor side of the window outer frame, a fifth drainage hole is arranged on the left side of the window outer frame drainage cavity, and a sixth drainage hole is arranged on the right side of the window outer frame drainage cavity;

the first drain hole, the second drain hole, the third drain hole, the fourth drain hole and the fifth drain hole are sequentially arranged from top to bottom, the sixth drain hole is located on the outer side of the fifth drain hole, and the sixth drain hole is communicated with the outdoor space.

2. The energy-saving outward-opening window drainage structure of claim 1, characterized in that: the window sash comprises a first window sash frame, a second window sash frame and a window sash frame heat insulation strip, and the first window sash frame and the second window sash frame are connected through the window sash frame heat insulation strip.

3. The energy-saving outward-opening window drainage structure of claim 1, characterized in that: the sash auxiliary frame comprises a first sash auxiliary frame, a second sash auxiliary frame and a sash auxiliary frame heat insulation strip; the first sash auxiliary frame and the second sash auxiliary frame are connected through the sash auxiliary frame heat insulation strip.

4. The energy-saving outward-opening window drainage structure of claim 1, characterized in that: the window frame comprises a first window frame, a second window frame and a window frame heat insulation strip, and the first window frame and the second window frame are connected through the window frame heat insulation strip.

5. The energy-saving outward-opening window drainage structure of claim 1, characterized in that: and in the first drain hole, the second drain hole, the third drain hole, the fourth drain hole and the fifth drain hole, the drain holes in the vertical adjacent directions are in staggered arrangement, and the fifth drain hole and the sixth drain hole are in staggered arrangement.

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