CN220336748U - Window structure capable of being turned upwards and turned over - Google Patents

Abstract

The application provides a window structure that can turn over and overturn, window structure includes window, upset frame, turns over frame and fixed frame upward, the window install in the upset frame, the middle part of upset frame with the middle part swivelling joint of turning over the frame upward, the top of turning over the frame with the top swivelling joint of fixed frame. The window structure that this application provided has solved the unable problem of installing the screen window of traditional roll-over window. In addition, the window structure that this application provided both has traditional turnover window and is convenient for clean advantage still has traditional turnover window and opens the indoor advantage of ability avoiding rainwater to invade in a large number under the state, when will turn over frame and turnover frame and adjust to the position that is certain contained angle in addition, sunshine mainly gets into indoor from turnover frame and upward turnover frame contained angle, so can reach better sunshade effect in ventilation to, can satisfy different sunshade demands through the contained angle that changes turnover frame and upward turnover frame.

Description

Window structure capable of being turned upwards and turned over

Technical Field

The application relates to the technical field of window structures, in particular to a window structure capable of being turned up and turned over.

Background

The roll-over window can switch the outer side surface of the window to the indoor side through roll-over, so that the roll-over window has the characteristic of easy cleaning, and is widely applied.

The current turnover window is directly with turnover frame swivelling joint in fixed frame, if install the screen window in the enclosure space of fixed frame and can interfere turnover frame rotation, consequently, unable installation screen window. In addition, the heat insulation performance and the sound insulation performance of the current turnover window are also to be improved.

Therefore, how to optimize the structure of the roll-over window is a technical problem that needs to be solved by those skilled in the art.

Disclosure of Invention

In order to solve the technical problems, the application provides a window structure capable of being turned up and turned over, the window structure comprises a window, a turning frame, an up frame and a fixed frame, the window is arranged on the turning frame, the middle part of the turning frame is rotatably connected with the middle part of the up frame, the top of the up frame is rotatably connected with the top of the fixed frame,

in one embodiment of the window structure, the upturned frame and the overturned frame are provided with a mounting groove for mounting the bearing, and the upturned frame and the overturned frame are provided with a protruding shaft which is used for being matched with an inner hole of the bearing, and the upturned frame and the overturned frame are rotatably connected through the bearing.

In one embodiment of the window structure, the upturning frame and the fixing frame are rotatably connected through a hinge, a first blade of the hinge is fixed on the lower side face of the top beam of the fixing frame, and a second blade of the hinge is fixed on the upper side face of the top beam of the upturning frame.

One implementation mode of the window structure is characterized in that a first page plate of the hinge and the lower side face of the top cross beam of the fixed frame are provided with grooves, and protrusions are arranged on the first page plate and the lower side face of the top cross beam of the fixed frame, and the first page plate and the lower side face of the top cross beam of the fixed frame are in concave-convex fit through the grooves and the protrusions.

In one embodiment of the window structure, the upturning frame is provided with an inner baffle and an outer baffle protruding out of the upper side face of the top cross beam of the upturning frame, and in the closed state of the window structure, the inner baffle is abutted against the inner side face of the top cross beam of the fixed frame, and the outer baffle is abutted against the outer side face of the top cross beam of the fixed frame.

In one embodiment of the window structure, the upturning frame is provided with a baffle protruding out of the lower side surface of the top cross beam of the upturning frame and a track connected with the baffle in a sliding mode, the baffle can be switched to the inner side or the outer side of the upturning frame in a sliding mode along the track, and in a closed state of the window structure, the baffle is abutted to the inner side or the outer side of the upturning frame.

One embodiment of the window structure comprises a supporting mechanism for stabilizing the upturning frame at a target opening, the supporting mechanism comprises a sliding rail and a telescopic piece, the sliding rail is fixedly connected with the upturning frame, one end of the telescopic piece is rotatably connected with the fixed frame, the other end of the telescopic piece is slidably connected with the sliding rail, the sliding rail is provided with a first positioning part for limiting sliding of the telescopic piece, and the telescopic piece is provided with a second positioning part for limiting telescopic of the telescopic piece.

In one embodiment of the window structure, the window comprises a glass layer, an air layer disposed between the two glass layers, and a porous material layer disposed within the air layer.

In one embodiment of the window structure, the porous material layer is an aerogel layer.

In one embodiment of the window structure, the window comprises a reel and an actuating mechanism, the porous material layer is wound on the periphery of the reel, the actuating mechanism is connected with the reel and is used for driving the reel to rotate bidirectionally so as to enable the porous material layer to spread into the air layer or roll back from the air layer, and the actuating mechanism is provided with a power component or acts along with the rotation of the turnover frame.

In one embodiment of the window structure, a flexible protective layer is arranged around the window and between the turnover frames.

One embodiment of the window structure includes a screen mounted to the fixed frame.

In one embodiment of the window structure, the cavities of the fixed frame, the upturned frame, the top cross beam, the bottom cross beam and the side beams of the upturned frame are filled with fillers.

In one embodiment of the window structure, the filler is sound absorbing cotton and aerogel.

The window structure that this application provided has solved the unable problem of installing the screen window of traditional roll-over window.

The window structure provided by the application has the advantages that the traditional turnover window is convenient to clean, and the window structure also has the advantage that rainwater can be prevented from invading a large amount of rooms under the traditional open state of the upward turnover window.

The window structure that this application provided, when will turn over the frame with turn over the frame and adjust to the position that is certain contained angle, sunshine mainly gets into indoor from turn over the frame and turn over the frame contained angle upward, so can reach better sunshade effect when ventilating to, can satisfy different sunshade demands through changing the contained angle of both.

The window structure that this application provided has better thermal insulation performance and sound insulation performance.

Drawings

FIG. 1 is a perspective view of one embodiment of a window structure provided herein;

FIG. 2 is a cross-sectional view of a hinge and upturned frame;

FIG. 3 is a schematic view of an embodiment of a bearing;

FIG. 4 is a cross-sectional view of the top cross-beam of the fixed frame;

FIG. 5 is a cross-sectional view of the baffle of the upturned frame in abutment with the inside or outside of the upturned frame;

FIG. 6 is a schematic view of an embodiment of a support mechanism;

FIG. 7 is a cross-sectional view of a roll-over frame and window with the porous material layer of the window in a spread state;

FIG. 8 is a cross-sectional view of a roll-over frame and window with the porous material layer of the window in a rolled-up state;

fig. 9 is a cross-sectional view of a folding screen.

The reference numerals are explained as follows:

10 windows, 101 glass layers, 102 air layers, 103 porous material layers, 104 reels;

20 the frame is turned over and,

30 up-turned frames, 301 inner baffles, 302 outer baffles, 303 baffles, 304 tracks, A mounting grooves;

40 fixing frame, C groove, D screen window rail;

50 bearings, 501 inner holes, 502 outer rings and 503 sealing separation blades;

60 hinges, 601 a first page, 602 a second page, and B protrusions;

70 supporting mechanism, 701 slide rail, 701a first positioning part, 702 telescopic piece, 702a second positioning part, 703 hinge;

80 a flexible protective layer;

90 folding screen, 901 screening box, 902 pull rod, 902a slider, 903 screening.

Detailed Description

In order to make those skilled in the art better understand the technical solutions of the present application, the technical solutions of the present application are further described in detail below with reference to the accompanying drawings and the detailed description.

As shown in fig. 1, the window structure provided herein includes a window 10, a roll-over frame 20, a roll-up frame 30, and a fixed frame 40. The window 10 is mounted to the roll-over frame 20. The middle part of the turnover frame 20 is rotatably connected with the middle part of the upturned frame 30. The top of the upturned frame 30 is rotatably connected with the top of the fixed frame 40.

As shown in fig. 1, after the upturning frame 30 is upturned, the upturning frame 20 can be brought to a position deviated from the fixed frame 40 by a certain distance, so that the rotation of the upturning frame 20 at the position does not occupy the enclosing space of the fixed frame 40, and thus, a screen window can be installed in the enclosing space of the fixed frame 40, and the screen window does not influence the rotation of the upturning frame 20.

The window structure that this application provided has solved the unable problem of installing the screen window of traditional roll-over window. In addition, the window structure provided by the application has the advantages that the traditional turnover window is convenient to clean (the outer side surface of the window 10 can be switched to the indoor side by the rotation of the turnover frame 20, so that the window is convenient to clean), and the window structure has the advantages that a large amount of rainwater can be prevented from invading the indoor side in the traditional turnover window opening state.

In addition, when the frame is turned over with turning over to the position that is certain contained angle with turning over the frame adjustment, sunshine mainly gets into indoor from the frame that turns over with turning over the frame contained angle, so can reach better sunshade effect when ventilating to, can satisfy different sunshade demands through changing the contained angle between them.

Specifically, the upturned frame 30, the turned frame 20 and the fixed frame 40 each include a side beam, a top beam and a bottom beam. The middle part of the side member of the roll-over frame 20 and the middle part of the side member of the roll-up frame 30 are rotatably connected. The middle part is understood in a broad sense, and may be the longitudinal direction of the side member toward the center position, or may be the vicinity of the longitudinal direction of the side member toward the center position.

In one embodiment, as shown in fig. 1, a screen window is installed in the enclosing space of the fixing frame 40 of the window structure, and the application is not limited to the type of screen window, for example, a invisible screen window, a folding screen window, a fixing screen window, etc. can be used.

In the drawing, the folding screen 90 includes a screen case 901, a screen 903, and a pull rod 902, and the top and bottom of the pull rod 902 may be provided with a slider 902a, and the slider 902a is slidably engaged with a screen rail D (see fig. 4) provided on the upper side of the bottom rail and the lower side of the top rail of the fixed frame 40.

In one embodiment, as shown in fig. 4, the side beams of the upturned frame 30 are provided with mounting grooves a for mounting the bearings 50, and the side beams of the upturned frame 20 are provided with protruding shafts for fitting with the inner holes 501 of the bearings 50, and the positions of the mounting grooves a and the protruding shafts can be exchanged. The upturned frame 30 and the upturned frame 20 are rotatably connected by a bearing 50. The outer ring 502 of the bearing 50 is fixed in the mounting groove a, the inner hole 501 of the bearing 50 is matched with the protruding shaft, and sealing retainers 503 are arranged at the end faces of two ends of the bearing 50 (see fig. 5. The bearing 50 shown in fig. 5 is a ball bearing, of course, the type of the bearing 50 can be flexibly selected according to actual needs, and the bearing is not limited to the ball bearing.

The upturned frame 30 and the upturned frame 20 are rotatably connected through the bearing 50, so that the manufacturing cost of the product is reduced and the service life of the product is ensured.

In one embodiment, as shown in FIG. 4, the flip-up frame 30 and the fixed frame 40 are rotatably connected by a hinge 60. The hinge 60 has a first leaf 601 and a second leaf 602 rotatably connected, the first leaf 601 of the hinge 60 is fixed to the lower side of the top beam of the fixed frame 40, the second leaf 602 of the hinge 60 is fixed to the upper side of the top beam of the flip-up frame 30,

the upturning frame 30 and the fixed frame 40 are rotatably connected through the hinge 60, so that the implementation is convenient, and the product cost is reduced.

Of course, the rotatable connection of the upturned frame 30 and the upturned frame 20 and the rotatable connection of the upturned frame 30 and the fixed frame 40 can be flexibly designed according to the needs, and are not limited to the bearing connection and the hinge connection.

In one embodiment, the first plate 601 of the hinge 60 is provided with a protrusion B (see fig. 4), and the lower side of the top beam of the fixing frame 40 is provided with a groove C (see fig. 3), so that the positions of the protrusion B and the groove C can be exchanged. The shape and size of the groove C are matched with those of the protrusion B, so that the first page 601 of the hinge 60 and the top cross beam of the fixed frame 40 are in concave-convex fit through the groove C and the protrusion B. In this way, the air tightness between the upturning frame 30 and the fixing frame 40 can be improved, and the heat insulation performance and the sound insulation performance of the window structure can be improved.

In one embodiment, as shown in FIG. 4, the upturned frame 30 has an inner baffle 301 and an outer baffle 302 protruding from the upper side of its top cross member. In the closed state of the window structure, the inner baffle 301 abuts against the inner side surface of the top beam of the fixed frame 40, and the outer baffle 302 abuts against the outer side surface of the top beam of the fixed frame 40. In this way, the air tightness between the upturning frame 30 and the fixing frame 40 can be improved, which is beneficial to improving the heat insulation performance and the sound insulation performance of the window structure.

If the up-turned frame 30 is turned open outward, the height of the inner barrier 301 may be set lower than the height of the outer barrier 302 so as not to interfere with the turning of the up-turned frame 30, and similarly, if the up-turned frame 30 is turned open inward, the height of the outer barrier 302 may be set lower than the height of the inner barrier 301 so as not to interfere with the turning of the up-turned frame 30,

in one embodiment, as shown in fig. 4, the upturned frame 30 has a baffle 303 protruding from the underside of the top beam thereof and a rail 304 slidably connected to the baffle 303, the baffle 303 being capable of being slidably switched along the rail 304 to the inside or outside of the upturned frame 30. As shown in fig. 6, in the closed state of the window structure, the shutter 303 abuts against the inside or outside of the roll-over frame 20. The baffle 303 is arranged, so that the air tightness between the upturning frame 30 and the upturning frame 20 can be improved, and the heat insulation performance and the sound insulation performance of the window structure can be improved. Allowing the flap 303 to switch along the track 304 to the inside or outside of the upturned frame 30 without affecting the turning of the upturned frame 20.

In one embodiment, the window structure is provided with a support mechanism 70 (see FIG. 1). The support mechanism 70 is used for supporting the upturning frame 30, so that the upturning frame 30 is stabilized at a target opening degree. In fig. 1, two support mechanisms 70 are provided, and the two support mechanisms 70 are respectively connected between the same side members of the fixed frame 40 and the upturned frame 30.

In one embodiment, as shown in fig. 7, the support mechanism 70 includes a sliding rail 701 and a telescopic member 702. The slide rail 701 is fixedly connected to the upturned frame 30. One end of the telescopic member 702 is rotatably connected to the fixed frame 40, and in particular may be rotatably connected to a hinge 703, the hinge 703 is fixedly connected to the fixed frame 40, and the rotatable connection with the fixed frame 40 is indirectly achieved through the hinge 703. The other end of the telescoping member 702 is slidably connected to the slide rail 701. The slide rail 701 is provided with a first positioning portion 701a that restricts the sliding of the telescopic member 702. The telescoping member 702 is provided with a second positioning portion 702a that restricts telescoping of the telescoping member 702.

Along with the gradual upward turning of the upward turning frame 30, the telescopic member 702 gradually extends, one end of the telescopic member 702 rotates relative to the fixed frame 40, the other end slides relative to the upward turning frame 30, and when the upward turning frame 30 is turned up to a target opening, the second positioning portion 702a of the telescopic member 702 plays a positioning role, so that the length of the telescopic member 702 is not changed any more, the first positioning portion 701a of the sliding rail 701 plays a positioning role, so that the telescopic member 702 does not slide relative to the upward turning frame 30 any more, and therefore, the upward turning frame 30 can be stabilized at the target opening.

Specifically, only one first positioning portion 701a and one second positioning portion 702a may be provided. A plurality of first positioning portions 701a and a plurality of second positioning portions 702a may be provided, where the plurality of first positioning portions 701a are respectively distributed at different length positions of the slide rail 701, and the plurality of second positioning portions 702a are respectively distributed at different length positions of the telescopic member 702, so that the upturning frame 30 can be positioned to a plurality of different openings.

In one embodiment, as shown in fig. 8, the window 10 includes a glass layer 101, an air layer 102 disposed between the two glass layers 101, and a porous material layer 103 disposed within the air layer 102. The number of glass layers 101 may be two or more. The window 10 of this construction has good thermal and acoustic insulation properties.

In one embodiment, the porous material layer 103 is an aerogel layer. The aerogel has large porosity and small heat conductivity coefficient (about 0.018W/m.K), and has excellent heat insulation and sound insulation performances. Of course, the porous material layer 103 of other materials may be used.

In one embodiment, as shown in fig. 8, the window 10 includes a spool 104 and an actuating mechanism (not shown), and the porous material layer 103 is wound around the periphery of the spool 104.

The action mechanism is connected with the reel 104, and is used for driving the reel 104 to rotate bidirectionally, the forward rotation of the reel 104 can drive the porous material layer 103 to spread into the air layer 102 to cover the whole section of the air layer 102 (see fig. 8), and the reverse rotation of the reel 104 can roll the porous material layer 103 back from the air layer 102 (see fig. 9).

In one embodiment, the actuating mechanism is provided with a power component, and the power component can be an electric component (such as a motor), and the electric component can be powered to drive the scroll 104 to rotate, or can be a manual component to manually drive the scroll 104 to rotate.

In one embodiment, the power mechanism does not have a power component, and the power mechanism drives the reel 104 to rotate along with the rotation of the turnover frame 20, and the power mechanism can be a chain transmission mechanism, a link mechanism, and the like.

In one embodiment, as shown in fig. 8, a flexible protective layer 80 is provided around the window 10 and between the roll-over frame 20. Thus, the air tightness between the window 10 and the turnover frame 20 can be improved, and the heat insulation performance and the sound insulation performance of the window structure can be improved.

In one embodiment, the cavities of the top cross member, bottom cross member and side members of the fixed frame 40, the upturned frame 30, and the overturned frame 20 are filled with filler, so that the thermal insulation performance and the sound insulation performance of the window structure can be improved.

In one embodiment, the filler is a sound absorbing surface and aerogel, although other types of fillers are possible.

The above embodiments may be combined with each other without conflict.

To sum up, the core idea of this application is to set up simultaneously and turn over frame 30 and upset frame 20, turns over frame 20 swivelling joint in last frame 30, and this application has synthesized the advantage of turning over window and upset window, has solved the unable problem of installing the screen window of traditional upset window, on this basis, this application has still promoted the thermal insulation performance and the sound insulation performance of window structure through various structural design.

It should be noted that, in the foregoing description, the terms "inner", "outer", "upper" and "lower" are used for convenience in understanding the relative positional relationship of the components of the present application, and do not represent that the present application can only be applied in such directions.

The foregoing has outlined the principles and embodiments of the present application with the understanding that the present application is directed to a method and core idea of the present application. It should be noted that it would be obvious to those skilled in the art that various improvements and modifications can be made to the present application without departing from the principles of the present application, and such improvements and modifications fall within the scope of the claims of the present application.

Claims (14)

1. The utility model provides a window structure that can turn up and overturn, its characterized in that, window structure includes window (10), upset frame (20), goes up upset frame (30) and fixed frame (40), window (10) install in upset frame (20), the middle part of upset frame (20) with the middle part swivelling joint of upturning frame (30), the top of upturning frame (30) with the top swivelling joint of fixed frame (40).

2. Window structure according to claim 1, characterized in that the upturned frame (30) and the overturned frame (20), one provided with a mounting groove (a) for mounting a bearing (50), and one provided with a male shaft for adapting to an inner bore (501) of the bearing (50), both being rotatably connected by means of the bearing (50).

3. The window structure according to claim 1, characterized in that the upturned frame (30) and the fixed frame (40) are rotatably connected by means of a hinge (60), a first leaf (601) of the hinge (60) being fixed to the underside of the top beam of the fixed frame (40), and a second leaf (602) of the hinge (60) being fixed to the upper side of the top beam of the upturned frame (30).

4. A window arrangement according to claim 3, characterized in that the first plate (601) of the hinge (60) and the underside of the top cross member of the fixed frame (40), one provided with a recess (C) and one provided with a projection (B), both of which are in a male-female fit by means of the recess (C) and the projection (B).

5. The window structure according to claim 1, wherein the upturned frame (30) has an inner baffle (301) and an outer baffle (302) protruding from an upper side of a top beam thereof, the inner baffle (301) abutting against an inner side of the top beam of the fixed frame (40) and the outer baffle (302) abutting against an outer side of the top beam of the fixed frame (40) in a closed state of the window structure.

6. Window structure according to claim 1, characterized in that the upturned frame (30) has a baffle (303) protruding from the underside of its top cross beam and a track (304) in sliding connection with the baffle (303), the baffle (303) being able to be switched slidingly along the track (304) to the inside or outside of the upturned frame (30), the baffle (303) abutting the inside or outside of the overturned frame (20) in the closed state of the window structure.

7. The window structure according to claim 1, characterized in that the window structure comprises a supporting mechanism (70) for stabilizing the upturning frame (30) at a target opening, the supporting mechanism (70) comprises a sliding rail (701) and a telescopic member (702), the sliding rail (701) is fixedly connected to the upturning frame (30), one end of the telescopic member (702) is rotatably connected to the fixed frame (40), the other end of the telescopic member (702) is slidably connected to the sliding rail (701), the sliding rail (701) is provided with a first positioning portion (701 a) for limiting the sliding of the telescopic member (702), and the telescopic member (702) is provided with a second positioning portion (702 a) for limiting the telescopic member (702).

8. A window structure according to any of claims 1-7, characterized in that the window (10) comprises a glass layer (101), an air layer (102) arranged between two of the glass layers (101), a layer of porous material (103) arranged within the air layer (102).

9. Window structure according to claim 8, characterized in that the porous material layer (103) is an aerogel layer.

10. The window structure according to claim 8, characterized in that the window (10) comprises a reel (104) around which the porous material layer (103) is wound, and an action mechanism connected to the reel (104) for driving the reel (104) to rotate bi-directionally so as to spread the porous material layer (103) into the air layer (102) or to roll back from the air layer (102), the action mechanism acting from a powered member or with the rotation of the roll-over frame (20).

11. Window structure according to any of claims 1-7, characterized in that a flexible protective layer (80) is provided around the window (10) and between the roll-over frame (20).

12. A window arrangement according to any one of claims 1-7, characterised in that the window arrangement comprises a screen mounted to the fixed frame (40).

13. The window structure according to any one of claims 1-7, wherein the cavities of the fixing frame (40), the upturned frame (30), the top cross member, the bottom cross member and the side members of the overturned frame (20) are filled with filler.

14. The window structure of claim 13, wherein the filler is sound absorbing cotton and aerogel.