CN111005648B

CN111005648B - Rotary aluminum alloy door and window

Info

Publication number: CN111005648B
Application number: CN201911207843.8A
Authority: CN
Inventors: 陈春燕
Original assignee: Shanghai Hengjiang Curtain Wall Decoration Engineering Co ltd
Current assignee: Shanghai Hengjiang Curtain Wall Decoration Engineering Co ltd
Priority date: 2019-11-30
Filing date: 2019-11-30
Publication date: 2021-03-09
Anticipated expiration: 2039-11-30
Also published as: CN111005648A

Abstract

A rotary aluminum alloy door and window comprises a window frame and a window sash, wherein a first rotating assembly is arranged between the lower side of the window sash and the lower side of the inner wall of the window frame, and a second rotating assembly is arranged between the upper side of the window sash and the upper side of the inner wall of the window frame; a positioning assembly is arranged between the first rotating column and the first rotating hole, the positioning assembly comprises a sliding hole vertically formed in the bottom of the first rotating hole, a positioning column vertically connected in the sliding hole in a sliding mode, a positioning hole vertically formed in the bottom of the first rotating column, and a first spring which is arranged in the sliding hole and pushes the top of the positioning column to be embedded in the positioning hole, the positioning column and the positioning hole are circumferentially fixed, and the depth of the sliding hole is larger than or equal to the length of the positioning column; one side in the window frame room is provided with the control assembly. The top of the positioning column is embedded in the positioning hole through the upward elastic force of the first spring, and the positioning hole is circumferentially fixed with the positioning column which is fixedly connected with the window sash, so that the window sash is firmly fixed by the positioning column.

Description

Rotary aluminum alloy door and window

Technical Field

The invention relates to the technical field of windows, in particular to a rotary aluminum alloy door window.

Background

A window, architecturally, refers to an opening made in a wall or roof to allow light or air to enter a room. The window comprises a window frame and a window sash, wherein the window frame horizontally slides in the window frame, one glass surface of the window sash faces outdoors, and the other glass surface of the window sash faces indoors. In order to facilitate the cleaning of the window sash, the center of the bottom of the window sash is rotatably connected with the center of the bottom of the window frame, the center of the top of the window sash is rotatably connected with the center of the top of the window frame, and the window sash can horizontally rotate by 360 degrees. When a worker cleans a window, one side of the glass of the window sash faces outdoors, so that the side of the glass of the window sash is inconvenient to clean. In the prior art, a window frame and a window sash are not provided with corresponding fixed structures, and the window sash is fixed at a certain position only by the friction force between the window sash and the window frame. Therefore, when the outdoor has a large wind force, the window sash is easily rotated.

Disclosure of Invention

The invention aims to provide a rotary aluminum alloy door and window.

The above object of the present invention is achieved by the following technical solutions:

a rotary aluminum alloy door and window comprises a window frame and a window sash horizontally and rotatably connected to the inner side of the window frame, wherein a first rotating assembly is arranged between the lower side of the window sash and the lower side of the inner wall of the window frame, and a second rotating assembly is arranged between the upper side of the window sash and the upper side of the inner wall of the window frame; the first rotating assembly comprises a first rotating hole formed in the center of the lower side of the inner wall of the window frame and a first rotating column vertically fixed in the center of the lower side of the window sash, and the first rotating column is rotatably embedded in the first rotating hole; the second rotating assembly comprises a second rotating hole formed in the center of the upper side of the inner wall of the window frame and a second rotating column vertically fixed at the center of the upper side of the window sash, and the second rotating column is rotatably embedded in the second rotating hole; a positioning assembly is arranged between the first rotating column and the first rotating hole, the positioning assembly comprises a sliding hole vertically formed in the bottom of the first rotating hole, a positioning column vertically connected in the sliding hole in a sliding manner, a positioning hole vertically formed in the bottom of the first rotating column, and a first spring which is arranged in the sliding hole and pushes the top of the positioning column to be embedded in the positioning hole, the positioning column is circumferentially fixed with the positioning hole, and the depth of the sliding hole is greater than or equal to the length of the positioning column; and a control assembly for pushing the positioning column to move up and down is arranged on one side in the window frame chamber.

Through adopting above-mentioned scheme, thereby the downside of casement is connected the level through the rotation between first rotation post and the first rotation hole and is rotated in the inboard of window frame, and thereby the upside of casement rotates the inboard of being connected in the casement through the rotation between second rotation post and the second rotation hole further to make the casement stably rotate in the casement. When the staff cleared up glass, the staff can rotate the side of the window sash located outdoors to the indoor, and therefore the window sash is cleared up.

The top of the positioning column is embedded in the positioning hole through the upward elastic force of the first spring, and the positioning hole is circumferentially fixed with the positioning column which is fixedly connected with the window sash, so that the window sash is firmly fixed by the positioning column. When the window sash needs to be rotated, the positioning column can slide away from the positioning hole through the control assembly by an operator, and the window sash can horizontally rotate.

Preferably, eight first positioning planes are uniformly arranged on the side walls of the positioning holes at intervals, eight second positioning planes attached to the first positioning planes are arranged on the side walls of the positioning columns, and when the window sash just rotates to the inner side of the window frame completely, the first positioning planes are attached to the second positioning planes.

By adopting the above scheme, through the setting of first locating plane and second locating plane, the reference column passes through the first locating plane of second locating plane laminating in the locating hole to realize that the circumference between reference column and the first rotation post is fixed.

When the window sash just rotates to the inner side of the window frame completely, the first positioning planes are attached to the second positioning planes, and the eight first positioning planes are uniformly distributed around the positioning holes, so that when an operator opens the window sash, the top of each positioning column automatically slides into the corresponding positioning hole through upward elastic force of the spring every time the window sash rotates by 45 degrees, the window sash is fixed, and the window sash is still stable after being opened.

Preferably, the control assembly comprises a sliding groove vertically arranged on one side of the window frame and communicated with the inner side of the sliding hole, and a control rod penetrating through the sliding groove and sliding vertically, and the control rod is fixedly connected with the positioning column.

By adopting the above scheme, through the setting of sliding tray and control lever, the staff follows the vertical slip control lever of the length direction of sliding tray, control lever and reference column fixed connection to drive the vertical slip of reference column.

The sliding groove is limited by vertically sliding the control rod, so that the vertical sliding range of the positioning column is limited, and the positioning column is prevented from sliding away from the sliding hole.

Preferably, the control assembly further comprises a locking ring threadedly coupled to the control rod and abutting against the sash side wall.

Through adopting above-mentioned scheme, through the setting of locking ring, the staff is through rotatory locking ring butt on the lateral wall of window frame to make the firm butt of the lateral wall of reference column on the lateral wall of sliding hole, thereby be fixed in corresponding position with the reference column.

Preferably, a first guide groove for the first rotating column to slide into the first rotating hole is horizontally formed in the lower side of the inner wall of the window frame, one end of the first guide groove is communicated with the first rotating hole, and the other end of the first guide groove is communicated with one side in the window frame chamber; in the same way, a second guide groove for the second rotating column to slide into the second rotating hole is horizontally formed in the upper side of the inner wall of the window frame.

Through adopting above-mentioned scheme, through the setting of first guide way, first rotation post just slides to first rotation downthehole along first guide way through a port of first guide way. Through the setting of second guide way, the second rotates the post through a port of second guide way and slides to in the second rotation hole along the second guide way. Therefore, the first guide groove and the second guide groove facilitate installation of the window sash.

Preferably, the positioning hole is divided into a first accommodating hole and a second accommodating hole, and an opening of the positioning hole is formed in one end, far away from the second accommodating hole, of the first accommodating hole; the positioning columns are horizontally and rotatably connected with the first accommodating holes, the eight first positioning planes are vertically arranged in the second accommodating holes, and the bottoms of the first positioning planes are abutted against the supporting table; when the first rotating column is rotatably connected with the first containing hole, the first rotating column is abutted against the supporting table; when the positioning column is rotatably connected with the first accommodating hole, the positioning column is abutted against the supporting table; when the positioning column is embedded in the second accommodating hole, the first positioning plane is attached to the second positioning plane.

By adopting the above scheme, because the first rotating column and the second rotating column respectively slide into the first rotating hole and the second rotating hole respectively through the first guide groove and the second guide groove, the rotating connection between the window sash and the window frame is unstable. When a rotating column slides into the first rotating hole through the first guide groove, the bottom of the positioning column slides into the first accommodating hole and is horizontally and rotatably connected with the first accommodating hole, so that the positioning column enables the first rotating column to stably rotate in the first rotating hole, and further enables the window sash to stably rotate in the window frame.

When the window sash rotates to a corresponding position, the first positioning plane is flush with the second positioning plane, and the positioning column slides into the second accommodating hole through upward elastic force of the first spring, so that the window sash is fixed, and the window sash is prevented from being blown.

Preferably, the side wall of the positioning column is provided with a fixing hole for the end part of the control rod to be embedded and fixed, and the side wall of the sliding hole is vertically provided with a third positioning plane which is attached to the second positioning plane.

Through adopting above-mentioned scheme, through the setting of fixed orifices, the staff can slide the reference column to the sliding hole in, and make and give the fixed orifices on my pole towards the sliding tray, and the one end of control lever passes the sliding tray and inlays to establish and be fixed in the fixed orifices to accomplish the fixed connection with the reference column.

Through the setting of third locating surface, the reference column passes through the second locating surface and laminates in the third locating surface to fix a position the position of reference column, and then make the fixed orifices of reference column lateral wall towards the sliding tray opening, make things convenient for the installation of control lever.

Preferably, a limiting assembly is arranged between the second rotating hole and the second rotating column and comprises a limiting hole vertically formed in the bottom of the second rotating hole, a ball vertically and slidably connected into the limiting hole, a containing groove formed in the top of the second rotating column and used for embedding the lower part of the ball, and a second spring arranged in the limiting hole and fixedly connected between the ball and the bottom of the locating hole.

Through adopting above-mentioned scheme, the ball passes through the decurrent elasticity of second spring, makes ball part butt in the holding tank at second rotation top of the post portion to the top of casement can be stable carry out circumferential direction. Simultaneously, when dismantling the casement, the top of casement passes through ball surface arcwall face to press the ball to spacing downthehole, thereby make things convenient for the dismantlement of casement.

Preferably, an elastic gasket abutting against the periphery of the window sash is fixed to the inner side of the window frame.

By adopting the above scheme, through the arrangement of the elastic sealing gasket, the periphery of the window sash is abutted against the inner wall of the window frame through the elastic sealing gasket, so that the window sash and the window frame have better sealing performance, and rainwater and dust are prevented from entering the room.

In conclusion, the beneficial technical effects of the invention are as follows:

1. the lower side of the window sash is horizontally rotated on the inner side of the window frame through the rotary connection between the first rotary column and the first rotary hole, and the upper side of the window sash is further stably rotated on the inner side of the window sash through the rotary connection between the second rotary column and the second rotary hole. When the staff cleared up glass, the staff can rotate the side of the window sash located outdoors to the indoor, and therefore the window sash is cleared up.

2. The top of the positioning column is embedded in the positioning hole through the upward elastic force of the first spring, and the positioning hole is circumferentially fixed with the positioning column which is fixedly connected with the window sash, so that the window sash is firmly fixed by the positioning column. When the window sash needs to be rotated, the positioning column can slide away from the positioning hole through the control assembly by an operator, and the window sash can horizontally rotate.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a vertical cross-sectional view of the present invention;

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

FIG. 4 is a schematic view showing an internal structure of a first rotating cylinder;

fig. 5 is an enlarged schematic view of a portion a in fig. 4.

In the figure: 1. a window frame; 11. an arrow; 2. a window sash; 3. a first rotating assembly; 31. a first rotation hole; 32. a first rotating column; 33. a first guide groove; 4. a second rotating assembly; 41. a second rotation hole; 42. a second rotating cylinder; 43. a second guide groove; 5. a positioning assembly; 51. a slide hole; 511. a third positioning plane; 52. a positioning column; 521. a second positioning plane; 522. a fixing hole; 53. positioning holes; 531. a first housing hole; 532. a second housing hole; 533. a first location plane; 534. a support table; 54. a first spring; 6. a control component; 61. a sliding groove; 62. a control lever; 63. locking a ring; 7. a limiting component; 71. a limiting hole; 72. a ball bearing; 73. a second spring; 74. a containing groove; 8. an elastic gasket.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1 and 2, the rotary aluminum alloy door and window disclosed by the invention comprises a window frame 1 which is vertically fixed on a wall and is made of aluminum alloy, wherein the inner side of the window frame 1 is horizontally and rotatably connected with a window sash 2 made of aluminum alloy, the center of the lower side of the window sash 2 is horizontally and rotatably connected with the center of the lower side of the inner wall of the window frame 1 through a first rotating assembly 3, and the center of the upper side of the window sash 2 is horizontally and rotatably connected with the center of the upper side of the inner wall of the window frame 1 through a second rotating assembly 4. When the worker cleans the glass of the window sash 2, the worker can rotate the side of the window sash 2 located outdoors to the indoor, thereby cleaning.

Referring to fig. 2 and 3, the first rotating assembly 3 includes a first rotating column 32 and a first rotating hole 31, the first rotating column 32 is integrally and vertically fixed at the center of the lower side of the window sash 2, the circular first rotating hole 31 is vertically opened at the center of the lower side of the inner wall of the window frame 1, and the first rotating column 32 is rotatably embedded in the first rotating hole 31; similarly, the second rotating assembly 4 includes a second rotating column 42 and a second rotating hole 41, the second rotating column 42 is integrally and vertically fixed at the center of the upper side of the window sash 2, the circular second rotating hole 41 is vertically arranged at the center of the upper side of the inner wall of the window frame 1, and the second rotating column 42 is rotatably embedded in the second rotating hole 41.

Further be convenient for first rotation post 32 to install in first rotation hole 31, the first guide way 33 of U-shaped has been seted up to the downside level of window frame 1 inner wall, and the width of first guide way 33 is unanimous with the diameter of first rotation hole 31, and the one end of first guide way 33 communicates with each other with the inboard of first rotation hole 31, and the other end of first guide way 33 communicates with each other with the indoor one side of casement 2, and the bottom of first guide way 33 flushes with the bottom of first rotation hole 31. Therefore, the first rotary post 31 slides into the first rotary hole 31 through the port of the first guide groove 33.

It is further convenient that the second rotating column 42 is installed in the second rotating hole 41, the upper side of the inner wall of the window frame 1 is horizontally provided with a second guide groove 43 which is arranged opposite to the first guide groove 33, the width of the second guide groove 43 is consistent with the diameter of the second rotating hole 41, one end of the second guide groove 43 is communicated with the inner side of the second rotating hole 41, the other end of the second guide groove 43 is communicated with one indoor side of the window sash 2, and the bottom of the second guide groove 43 is flush with the bottom of the first rotating hole 31. Therefore, the second rotation hole 42 slides into the second rotation hole 41 through the port of the first guide groove 43.

Further prevent that first rotation post 32 from breaking away from first rotation hole 31, be provided with locating component 5 between first rotation post 32 and the window frame 1, locating component 5 includes sliding hole 51, reference column 52, first spring 54 and locating hole 53, and circular shape sliding hole 51 is vertical to be seted up in the center department of first rotation hole 31 bottom, and reference column 52 is vertical sliding connection in sliding hole 51, and the lateral wall of reference column 52 is laminated with sliding hole 51's lateral wall mutually, and the length of reference column 52 is less than the degree of depth of sliding hole 51. The first spring 54 is vertically disposed at the bottom of the sliding hole 51, the bottom of the first spring 54 abuts against the bottom of the sliding hole 51, and the top of the first spring 54 abuts against the bottom of the positioning pillar 52. The circular positioning hole 53 is vertically opened at the center of the bottom of the first rotating column 32 and is opposite to the sliding hole 51, and the top of the positioning column 52 is rotatably embedded in the positioning hole 53 through the upward elastic force of the first spring 54.

Referring to fig. 3 and 4 and 5, further rotation of the sash 2 to a position fixes the sash 2 in that position. The positioning hole 53 may be divided into a first accommodating hole 531 and a second accommodating hole 532, an opening of the positioning hole 53 is located at one end of the first accommodating hole 531, and a bottom of the positioning hole 53 is located at one end of the second accommodating hole 532. When the upper part of the positioning column 52 is embedded and fixed in the second containing hole 532, the top part of the positioning column 52 is rotatably connected with the first containing hole 531, and the window sash 2 can stably and horizontally rotate; meanwhile, eight first positioning planes 533 are vertically and uniformly arranged on the side wall of the second accommodating hole 532, the adjacent first positioning planes 533 are separated by an arc-shaped surface of the inner wall of the second accommodating hole 532, and a supporting table 534 is formed between the eight first positioning planes 533 and the inner wall of the first accommodating cavity 531. Eight second positioning planes 521 attached to the first positioning planes 533 are vertically disposed on the sidewalls of the positioning posts 52, and two ends of the second positioning planes 521 respectively extend to two ends of the positioning posts 52. Since the first positioning plane 533 is perpendicular to the bottom length direction of the window sash 2, when the window sash 2 is completely rotated to the inner side of the window frame 1, the positioning column 52 slides into the second accommodating hole 532.

Specifically, when the window sash 2 is completely rotated to the inner side of the window frame 1, the top of the positioning column 52 slides into the second accommodating hole 532, and the positioning column 52 realizes circumferential fixation between the positioning column 52 and the first rotating column 32 through the first positioning plane 533 and the second positioning plane 521, so as to fix the window sash 2. When the position of the window sash 2 needs to be opened, the worker slides the top of the positioning column 52 into the first position-limiting hole 71, and rotates the window sash 2, so that the top of the positioning column 52 abuts against the supporting table 534 through the upward elastic force of the first spring 54. When the window sash 2 rotates, the first positioning plane 533 of the inner wall of the second accommodating hole 532 is flush with the second positioning plane 521 of the side wall of the positioning column 52, the top of the positioning column 52 slides into the first accommodating hole 531 along the first positioning plane 533, so that circumferential fixing between the positioning column 52 and the first rotating column 32 is completed, and the window sash 2 is fixed. The eight first positioning planes 533 are uniformly arranged around the inner wall of the positioning hole 53, and the first positioning planes 533 are perpendicular to the length direction of the bottom of the window sash 22. Therefore, when the window sash 2 is closed and the worker needs to open the window sash 2, the first positioning plane 533 and the second positioning plane 521 are flush with each other every 45 degrees of rotation of the window sash 2, so as to fix the window sash 2.

Further controlling the position of the positioning post 52 sliding up and down, a control assembly 6 is arranged between the positioning post 52 and the window frame 1, the control assembly 6 comprises a sliding groove 61, a control rod 62 and a locking ring 63, the sliding groove 61 is vertically arranged at the lower part of the indoor side of the window frame 1, and the sliding hole 51 is communicated with the sliding groove 61. A circular fixing hole 522 is horizontally formed in the side wall of the positioning column 52, one end of the control rod 62 horizontally penetrates through the sliding groove 61 and is embedded and fixed in the fixing hole 522, and the side wall of the control rod 62 is in sliding fit with two vertical side walls of the sliding groove 61; meanwhile, the locking ring 63 is screwed on the positioning post 52 and abuts against the side wall of the window frame 1. Specifically, the operator vertically slides the control rod 62 along the direction of the sliding groove 61, and the control rod 62 drives the positioning column 52 to move up and down, and the positioning column 52 is fixed at a certain position by rotating the locking ring 63.

The side wall of the sliding hole 51 is vertically provided with a third positioning plane 511, the second positioning plane 521 is connected to the lower side of the inner wall of the window frame 1, and the positioning column 52 is attached to the third positioning plane 511 through the second positioning plane 521, so that the positioning between the positioning column 52 and the sliding hole 51 is realized, the fixing hole 522 is aligned with the sliding groove 61, and the end of the control rod 62 can pass through the sliding groove 61 and be embedded and fixed in the fixing hole 522.

Referring to fig. 2, a limiting assembly 7 is disposed between the second rotating column 42 and the second rotating hole 41, and the limiting assembly 7 includes a limiting hole 71, a ball 72, a limiting groove, and a second spring 73. The circular limiting hole 71 is vertically arranged at the center of the second rotating hole 41, the ball 72 is embedded in the limiting hole 71 in a sliding manner, and the diameter of the ball 72 is the same as that of the limiting hole 71. A hemispherical limiting groove is formed in the center of the top of the second rotating column 42, the lower half part of the ball 72 is embedded in the limiting groove, and the upper half part of the ball 72 is embedded in the limiting hole 71; meanwhile, the second spring 73 is vertically arranged at the bottom of the limiting hole 71, the bottom of the second spring 73 is pasted on the ball 72, the top of the second spring 73 is pasted and fixed at the top of the limiting hole 71, the length of the second spring 73 is smaller than the depth of the limiting hole 71, and the ball 72 is always partially kept in the limiting hole 71.

Referring to fig. 1, a strip-shaped elastic sealing gasket 8 is arranged around the inner wall of the window frame 1, and when the window sash 2 is completely rotated into the window frame 1, the periphery of the window sash 2 abuts against the inner wall of the window frame 1 through the elastic sealing gasket 8.

The implementation principle of the embodiment is as follows: when installing window sash 2, the operator slides positioning post 52 into sliding hole 51 through control rod 62. The worker slides the first rotary post 32 into the first rotary hole 31 through a port of the first guide groove 33 and along the first guide groove 33, and slides the second rotary post 42 into the second rotary hole 41 through a port of the second guide groove 43 and along the second guide groove 43, thereby completing the installation of the window sash 2. At this time, the lower side and the upper side of the window sash 2 are respectively connected to the inner side of the window frame 1 through the first rotating column 32 and the second rotating column 42; meanwhile, when the window sash 2 is disassembled, the worker conceals the control lever 62 into the sliding hole 51 through the locking ring 63, thereby performing the disassembly of the window sash 2.

When the window sash 2 is locked, the top of the positioning column 52 is embedded in the second accommodating hole 532, and the positioning column 52 and the first rotating column 32 are circumferentially fixed by the first positioning plane 533 and the second positioning plane 521, so that the positioning column 52 prevents the window sash 2 from horizontally rotating, thereby enabling the window sash 2 to be stably in a closed state or an open state.

When the window sash 2 rotates, the top of the positioning column 52 is rotatably embedded in the first accommodating hole 531 and abuts against the supporting platform 534, and when the window sash 2 rotates until the first positioning plane 533 is flush with the second positioning plane 521, the positioning column 52 is embedded in the second accommodating hole 532 by the upward elastic force of the spring, thereby completing the locking of the window sash 2.

The embodiments of the present invention are preferred embodiments of the present invention, and the scope of the present invention is not limited by these embodiments, so: all equivalent changes made according to the structure, shape and principle of the invention are covered by the protection scope of the invention.

Claims

1. The utility model provides a rotation type aluminum alloy door and window, includes window frame (1) and horizontal rotation connect in window sash (2) of window frame (1) inboard, its characterized in that: a first rotating assembly (3) is arranged between the lower side of the sash (2) and the lower side of the inner wall of the window frame (1), and a second rotating assembly (4) is arranged between the upper side of the sash (2) and the upper side of the inner wall of the window frame (1);

the first rotating assembly (3) comprises a first rotating hole (31) formed in the center of the lower side of the inner wall of the window frame (1) and a first rotating column (32) vertically fixed to the center of the lower side of the window sash (2), and the first rotating column (32) is rotatably embedded in the first rotating hole (31);

the second rotating assembly (4) comprises a second rotating hole (41) formed in the center of the upper side of the inner wall of the window frame (1) and a second rotating column (42) vertically fixed to the center of the upper side of the window sash (2), and the second rotating column (42) is rotatably embedded in the second rotating hole (41);

a positioning assembly (5) is arranged between the first rotating column (32) and the first rotating hole (31), the positioning assembly (5) comprises a sliding hole (51) vertically formed in the bottom of the first rotating hole (31), a positioning column (52) vertically connected in the sliding hole (51) in a sliding manner, a positioning hole (53) vertically formed in the bottom of the first rotating column (32), and a first spring (54) arranged in the sliding hole (51) and used for pushing the top of the positioning column (52) to be embedded in the positioning hole (53), the positioning column (52) and the positioning hole (53) are circumferentially fixed, and the depth of the sliding hole (51) is greater than or equal to the length of the positioning column (52); eight first positioning planes (533) are uniformly arranged on the side walls of the positioning holes (53) at intervals, eight second positioning planes (521) attached to the first positioning planes (533) are arranged on the side walls of the positioning columns (52), and when the window sash (2) just rotates to the inner side of the window frame (1) completely, the first positioning planes (533) are attached to the second positioning planes (521);

the positioning hole (53) is divided into a first containing hole (531) and a second containing hole (532), and an opening of the positioning hole (53) is formed in one end, far away from the second containing hole (532), of the first containing hole (531); the positioning columns (52) are horizontally and rotatably connected with the first containing holes (531), the eight first positioning planes (533) are vertically arranged in the second containing holes (532), and the bottoms of the first positioning planes (533) are abutted against the support table (534); when the positioning column (52) is rotatably connected with the first containing hole (532), the positioning column (52) abuts against the supporting table (534); when the positioning column (52) is embedded in the second accommodating hole (532), the first positioning plane (533) is attached to the second positioning plane (521);

a control assembly (6) for pushing the positioning column (52) to move up and down is arranged on one indoor side of the window frame (1); the control assembly (6) comprises a sliding groove (61) which is vertically arranged on one side of the window frame (1) and communicated with the inner side of the sliding hole (51), and a control rod (62) which penetrates through the sliding groove (61) and vertically slides, wherein the control rod (62) is fixedly connected with the positioning column (52).

2. The rotary aluminum alloy door and window according to claim 1, wherein: the control assembly (6) further comprises a locking ring (63) which is connected to the control rod (62) in a threaded mode and abuts against the side wall of the window frame (1).

3. The rotary aluminum alloy door and window according to claim 1, wherein: a first guide groove (33) for the first rotating column (32) to slide into the first rotating hole (31) is horizontally formed in the lower side of the inner wall of the window frame (1), one end of the first guide groove (33) is communicated with the first rotating hole (31), and the other end of the first guide groove (33) is communicated with one indoor side of the window frame (1); similarly, a second guide groove (43) for the second rotating column (42) to slide into the second rotating hole (41) is horizontally formed on the upper side of the inner wall of the window frame (1).

4. The rotary aluminum alloy door and window according to claim 1, wherein: the side wall of the positioning column (52) is provided with a fixing hole (522) for the end part of the control rod (62) to be embedded and fixed, and the side wall of the sliding hole (51) is vertically provided with a third positioning plane (511) attached to the second positioning plane (521).

5. The rotary aluminum alloy door/window according to claim 3, wherein: second rotate hole (41) with be provided with spacing subassembly (7) between second rotation post (42), spacing subassembly (7) including vertical set up in spacing hole (71), vertical sliding connection in spacing downthehole (71) of second rotation hole (41) bottom ball (72), set up in second rotation post (42) top just supplies ball (72) lower part inlays storage tank (74) of establishing, set up in spacing hole (71) and fixed connection in ball (72) with second spring (73) between locating hole (53) bottom.

6. The rotary aluminum alloy door and window according to claim 1, wherein: an elastic sealing gasket (8) which is abutted against the periphery of the window sash (2) is fixed on the inner side of the window frame (1).