CN113107313A

CN113107313A - Bidirectional movement high-performance sliding window

Info

Publication number: CN113107313A
Application number: CN202110584466.0A
Authority: CN
Inventors: 高校
Original assignee: Jiangsu Lujian Construction Technology Co ltd
Current assignee: Jiangsu Lujian Construction Technology Co ltd
Priority date: 2021-05-27
Filing date: 2021-05-27
Publication date: 2021-07-13
Anticipated expiration: 2041-05-27
Also published as: CN113107313B

Abstract

The invention discloses a bidirectional-movement high-performance sliding window which comprises a window frame, a bidirectional-movement sliding sash frame, a multifunctional assembly and a non-uniform-thickness anti-resonance glass system, wherein the bidirectional-movement sliding sash frame and the multifunctional assembly are respectively positioned in the window frame, and the non-uniform-thickness anti-resonance glass system is positioned in the window frame and the bidirectional-movement sliding sash frame. Has the advantages that: realize water proof, sunshade, new trend, antifog haze integration, compact structure is novel, dismantle and change easy, preparation and simple to operate, and economy can bear the advantage big, is suitable for new building door and window application and the transformation of existing building old window, can pass through inflatable structure simultaneously for form the air film between window frame and the two-way removal push-and-pull fan frame, thereby be convenient for the promotion of two-way removal push-and-pull fan frame.

Description

Bidirectional movement high-performance sliding window

Technical Field

The invention relates to the technical field of sliding windows, in particular to a bidirectional-movement high-performance sliding window.

Background

The sliding window is widely applied to the field of buildings due to the characteristics of attractive appearance, convenience in opening and closing and no occupation of indoor space, and the sliding window has the biggest defect of poor water tightness and heat preservation, is not suitable for modern energy-saving requirements and is therefore out of order. But the sliding window has many advantages and is popular with users. The method is beneficial to cheating removal and optimization, and is very important to develop an excellent new product. The present invention has been developed in response to this need.

An effective solution to the problems in the related art has not been proposed yet.

Disclosure of Invention

Aiming at the problems in the related art, the invention provides a bidirectional moving high-performance sliding window to overcome the technical problems in the prior related art.

Therefore, the invention adopts the following specific technical scheme:

a bidirectional-movement high-performance sliding window comprises a window frame, a bidirectional-movement sliding sash frame, a multifunctional assembly and a variable-thickness anti-resonance glass system, wherein the bidirectional-movement sliding sash frame and the multifunctional assembly are respectively positioned inside the window frame, the variable-thickness anti-resonance glass system is positioned inside the window frame and the bidirectional-movement sliding sash frame, the window frame is composed of a plurality of aluminum alloy section bars, the aluminum alloy section bars are of an end-to-end connection structure, one side of the aluminum alloy section bars is provided with a sash frame connecting clamping groove and a multifunctional assembly connecting clamping groove, the sash frame connecting clamping groove is connected with the bidirectional-movement sliding sash frame in a matching manner, the multifunctional assembly connecting clamping groove is connected with the multifunctional assembly in a matching manner, the bidirectional-movement sliding sash frame is composed of a plurality of sash frame units and a bidirectional controller, the bidirectional controller is connected between the sash frame units and the window frame, the multifunctional component consists of a water baffle I, a water baffle II, a filter screen, a frame, a pressing strip I, a pressing strip II, a pressing strip III and a pressing strip IV, the first water baffle and the second water baffle are respectively connected with the two sides of the frame, the filter screen is positioned inside the first water baffle and the second water baffle, the first pressing strip and the second pressing strip are respectively positioned on the side edges of the two sides of the first water baffle plate, the third pressing strip and the fourth pressing strip are respectively positioned on the side edges of the two sides of the second water baffle plate, the variable-thickness anti-resonance glass system is composed of a first double-glass hollow glass, a second double-glass hollow glass, a built-in sun-shading assembly and a glass supporting frame body, the first double-glass hollow glass and the second double-glass hollow glass are both fixedly connected inside the glass supporting frame body, the built-in sunshade assembly is located between the first double-glass hollow glass and the second double-glass hollow glass and fixedly connected with the glass supporting frame body.

Furthermore, a central inner cavity is formed in the aluminum alloy section I, a plurality of side inner cavities I are formed in one side of the inner portion of the aluminum alloy section I, and a plurality of side inner cavities II are formed in the other side of the inner portion of the aluminum alloy section I.

Furthermore, the sash frame unit is composed of a plurality of aluminum alloy section bars II, the aluminum alloy section bars II are of an end-to-end connection structure, one side of the aluminum alloy section bars II is provided with a glass system clamping assembly matched with the anti-resonance glass system with different thicknesses, and a plurality of rectangular inner cavities are formed in the aluminum alloy section bars II.

Further, the central inner chamber the side inner chamber one the side inner chamber two with the inside of rectangle inner chamber all is filled respectively has syllable-dividing heat preservation inner core, syllable-dividing heat preservation inner core comprises puigging, first thermal-insulated heat preservation and the thermal-insulated heat preservation of second, first thermal-insulated heat preservation is located one side of puigging, the thermal-insulated heat preservation of second is located the opposite side of puigging, the puigging is cellular structure, the puigging with first thermal-insulated heat preservation with the thermal-insulated heat preservation of second is hot pressing connection structure.

Furthermore, the first pressing strip, the second pressing strip, the third pressing strip and the fourth pressing strip are all of U-shaped structures, and the first pressing strip, the second pressing strip, the third pressing strip and the fourth pressing strip are all of deformable structures.

Furthermore, the built-in sunshade component is of a lifting folding structure, and two sides inside the glass supporting frame body are respectively provided with a driving regulator which is matched and connected with the built-in sunshade component.

Furthermore, a plurality of limiting slide ways are arranged at the bottom end inside the window frame, a plurality of movable rollers matched with the limiting slide ways are arranged at the bottom end of the bidirectional moving push-pull fan frame, the movable rollers are matched and connected with the bidirectional moving push-pull fan frame through movable shafts, and the movable rollers are made of stainless steel.

Furthermore, a pressurizing air pump is arranged at the bottom end of one side of the window frame, an airflow groove communicated with the pressurizing air pump is arranged at the bottom end inside the window frame, a plurality of inflation grooves communicated with the airflow groove are formed in the top end of the airflow groove, a plurality of sliding sealing blocks attached to the window frame are arranged at the bottom end of the bidirectional moving push-pull fan frame, and an air pressure chamber is formed between the sliding sealing blocks.

Furthermore, an electromagnetic valve is arranged inside the air inflation groove, a plurality of infrared reflection sensors are arranged on one side of the air inflation groove, and an infrared reflection mirror matched with the infrared reflection sensors is arranged at the top end inside the air pressure chamber.

The invention has the beneficial effects that: through setting up by the window frame, two-way movement push-and-pull fan frame, the two-way movement high performance austral window, sliding sash that multi-functional subassembly and the anti-resonance glass system that varies thickness constitute, thereby can realize the water proof, the sunshade, the new trend, antifog haze integration, compact structure is novel, dismantle and change easily, preparation and simple to operate, economy can bear the advantage greatly, be suitable for the transformation of new building door and window application and existing building old window, simultaneously can pass through inflatable structure, make and form the air film between window frame and the two-way movement push-and-pull fan frame, thereby be convenient for the promotion of two-way movement push-and.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a two-way moving high-performance sliding window according to an embodiment of the present invention;

figure 2 is one of the cross-sectional views of a two-way sliding high performance sash window in accordance with an embodiment of the present invention;

figure 3 is a second cross-sectional view of a two-way sliding high performance window in accordance with an embodiment of the present invention;

FIG. 4 is a schematic structural view of a sound-insulating and heat-insulating inner core of a two-way moving high-performance sliding window according to an embodiment of the invention;

FIG. 5 is a schematic structural diagram of a non-uniform thickness anti-resonance glass system of a two-way moving high-performance sliding window according to an embodiment of the present invention;

FIG. 6 is a schematic view of the connection between the window frame and the bottom end of the frame of the bidirectional sliding sash of the non-uniform thickness anti-resonance glass system of the bidirectional sliding high-performance sash according to the embodiment of the invention;

fig. 7 is a partially enlarged view of a portion a in fig. 6.

In the figure:

1. a window frame; 2. the sliding sash frame is moved in two directions; 3. a multifunctional component; 4. a non-uniform thickness anti-resonance glass system; 5. a first aluminum alloy section; 6. the fan frame is connected with the clamping groove; 7. the multifunctional component is connected with the clamping groove; 8. a central lumen; 9. a side inner cavity I; 10. a side inner cavity II; 11. a fan frame unit; 12. a bi-directional controller; 13. aluminum alloy section II; 14. a glass system clamping assembly; 15. a rectangular inner cavity; 16. a sound-insulation and heat-preservation inner core; 17. a sound insulating layer; 18. a first heat insulation layer; 19. a second heat insulation layer; 20. a water baffle I; 21. a water baffle II; 22. a filter screen; 23. a frame; 24. layering a first layer; 25. layering a second layer; 26. layering a third layer; 27. pressing a bar IV; 28. double-glass hollow glass I; 29. a second double-glass hollow glass; 30. a sunshade component is arranged inside; 31. a glass support frame; 32. driving the regulator; 33. a limiting slide way; 34. a movable roller; 35. a movable shaft; 36. a pressurized air pump; 37. an air flow groove; 38. an inflation groove; 39. sliding the sealing block; 40. an air pressure chamber; 41. an electromagnetic valve; 42. an infrared reflection sensor; 43. an infrared mirror.

Detailed Description

For further explanation of the various embodiments, the drawings which form a part of the disclosure and which are incorporated in and constitute a part of this specification, illustrate embodiments and, together with the description, serve to explain the principles of operation of the embodiments, and to enable others of ordinary skill in the art to understand the various embodiments and advantages of the invention, and, by reference to these figures, reference is made to the accompanying drawings, which are not to scale and wherein like reference numerals generally refer to like elements.

According to an embodiment of the invention, a two-way moving high-performance sliding window is provided.

The first embodiment is as follows:

as shown in fig. 1 to 7, the two-way moving high-performance sliding window according to the embodiment of the present invention includes a window frame 1, a two-way moving sliding sash frame 2, a multifunctional component 3, and a non-uniform thickness anti-resonance glass system 4, where the two-way moving sliding sash frame 2 and the multifunctional component 3 are respectively located inside the window frame 1, the non-uniform thickness anti-resonance glass system 4 is located inside the window frame 1 and the two-way moving sliding sash frame 2, the window frame 1 is formed by a plurality of aluminum alloy profiles one 5, the aluminum alloy profiles one 5 is an end-to-end connection structure, one side of the aluminum alloy profiles one 5 is provided with a sash frame connection slot 6 and a multifunctional component connection slot 7, the sash frame connection slot 6 is connected to the two-way moving sliding sash frame 2 in a matching manner, and the multifunctional component connection slot 7 is connected to the multifunctional component 3 in a, the bidirectional moving push-pull fan frame 2 is composed of a plurality of fan frame units 11 and a bidirectional controller 12, the bidirectional controller 12 is connected between the fan frame units 11 and the window frame 1, the multifunctional component 3 is composed of a first water baffle plate 20, a second water baffle plate 21, a filter screen 22, a frame 23, a first pressing strip 24, a second pressing strip 25, a third pressing strip 26 and a fourth pressing strip 27, the first water baffle plate 20 and the second water baffle plate 21 are respectively connected to two sides of the frame 23, the filter screen 22 is located inside the first water baffle plate 20 and the second water baffle plate 21, the first pressing strip 24 and the second pressing strip 25 are respectively located on side edges of two sides of the first water baffle plate 20, the third pressing strip 26 and the fourth pressing strip 27 are respectively located on side edges of two sides of the second water baffle plate 21, and the unequal-thickness anti-resonance glass system 4 is composed of a first double-glass hollow glass 28, a second double-glass hollow glass 29, The built-in sunshade component 30 and the glass supporting frame 31 are formed, the first double-glass hollow glass 28 and the second double-glass hollow glass 29 are fixedly connected inside the glass supporting frame 31, and the built-in sunshade component 30 is located between the first double-glass hollow glass 28 and the second double-glass hollow glass 29 and is fixedly connected with the glass supporting frame 31.

In one embodiment, the inside of the aluminum alloy section bar I5 is provided with a central inner cavity 8, one side of the inside of the aluminum alloy section bar I5 is provided with a plurality of side inner cavities I9, and the other side of the inside of the aluminum alloy section bar I5 is provided with a plurality of side inner cavities II 10.

In one embodiment, the sash frame unit 11 is composed of a plurality of aluminum alloy sections two 13, the aluminum alloy sections two 13 are in an end-to-end connection structure, one side of the aluminum alloy sections two 13 is provided with a glass system clamping assembly 14 matched with the unequal-thickness anti-resonance glass system 4, and the aluminum alloy sections two 13 are internally provided with a plurality of rectangular inner cavities 15.

In one embodiment, the central inner cavity 8, the first side inner cavity 9, the second side inner cavity 10 and the rectangular inner cavity 15 are respectively filled with a sound-insulating and heat-preserving inner core 16, the sound-insulating and heat-preserving inner core 16 is composed of a sound-insulating layer 17, a first heat-insulating layer 18 and a second heat-insulating layer 19, the first heat-insulating layer 18 is located on one side of the sound-insulating layer 17, the second heat-insulating layer 19 is located on the other side of the sound-insulating layer 17, the sound-insulating layer 17 is of a honeycomb structure, and the sound-insulating layer 17, the first heat-insulating layer 18 and the second heat-insulating layer 19 are in a hot-press connection structure.

In one embodiment, the first pressing strip 24, the second pressing strip 25, the third pressing strip 26 and the fourth pressing strip 27 are all U-shaped structures, and the first pressing strip 24, the second pressing strip 25, the third pressing strip 26 and the fourth pressing strip 27 are all deformable structures.

In one embodiment, the built-in sunshade assembly 30 is a foldable structure, and two sides of the inside of the glass supporting frame 31 are respectively provided with a driving regulator 32 which is cooperatively connected with the built-in sunshade assembly 30.

In one embodiment, a plurality of limiting slideways 33 are arranged at the bottom end inside the window frame 1, a plurality of movable rollers 34 matched with the limiting slideways 33 are arranged at the bottom end of the bidirectional moving push-pull fan frame 2, the movable rollers 34 are matched and connected with the bidirectional moving push-pull fan frame 2 through movable shafts 35, and the movable rollers 34 are made of stainless steel.

In one embodiment, a pressurized air pump 36 is disposed at the bottom end of one side of the window frame 1, an air flow groove 37 communicated with the pressurized air pump 36 is disposed at the bottom end of the interior of the window frame 1, a plurality of air inflation grooves 38 communicated with the air flow groove 37 are disposed at the top end of the air flow groove 37, a plurality of sliding sealing blocks 39 attached to the window frame 1 are disposed at the bottom end of the bidirectional sliding push-pull fan frame 2, and an air pressure chamber 40 is formed between the sliding sealing blocks 39.

In one embodiment, an electromagnetic valve 41 is arranged inside the air inflation groove 38, a plurality of infrared reflection sensors 42 are arranged on one side of the air inflation groove 38, and an infrared reflection mirror 43 matched with the infrared reflection sensors 42 is arranged at the top end inside the air pressure chamber 40.

The working principle is as follows: the multifunctional assembly 3 consisting of the water baffle plate I20, the water baffle plate II 21, the frame 23, the filter screen 22, the frame 23, the batten I24, the batten II 25, the batten III 26 and the batten IV 27 and the multifunctional assembly 3 consisting of the water baffle plate I20, the water baffle plate II 21, the filter screen 22, the frame 23, the batten II 24, the batten II 25, the batten III 26 and the batten IV 27 can realize the integral sealing effect of the window body and effectively avoid rainwater infiltration, and the multifunctional assembly is formed by the double-glass hollow glass I28, the side inner cavity I9, the side inner cavity II 10 and the rectangular inner cavity 15 and is filled with the sound and heat insulation inner core 16 consisting of the sound insulation layer 17, the first heat insulation layer 18 and the second heat insulation layer 19 in the central inner cavity 8, the side inner cavity I9, the side inner cavity II 10 and the rectangular inner cavity 15 The double-glass hollow glass II 29, the variable-thickness anti-resonance glass system 4 formed by the built-in sunshade component 30 and the glass supporting frame body 31 further improves the sunshade and separation effects of the variable-thickness anti-resonance glass system 4, when the bidirectional moving push-pull fan frame 2 is pushed and pulled, the air is inflated through the pressurizing air pump 36, the air enters the inflation groove 38 through the air flow groove 37, and therefore the air chamber 40 can be entered, an air film is formed between the window frame and the bidirectional moving push-pull fan frame, pushing of the bidirectional moving push-pull fan frame is facilitated, meanwhile, the opening and closing of the corresponding electromagnetic valve 41 are controlled through the positions of the infrared reflection sensor 42 and the infrared reflection mirror 43, and efficient utilization of the air is achieved.

In conclusion, by means of the technical scheme, the two-way moving high-performance sliding window consisting of the window frame 1, the two-way moving push-pull fan frame 2, the multifunctional component 3 and the unequal-thickness anti-resonance glass system 4 is arranged, so that integration of water resistance, sun shading, fresh air and haze prevention can be realized, the structure is compact and novel, the disassembly and replacement are easy, the manufacturing and the installation are convenient, the economic bearing advantage is high, the window frame is suitable for application of new building doors and windows and transformation of old building windows, and meanwhile, an air film is formed between the window frame and the two-way moving push-pull fan frame through an inflatable structure, so that the two-way moving push-pull fan frame is convenient to push.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "disposed," "connected," "secured," "screwed," and the like are to be construed broadly, e.g., as meaning permanently connected, detachably connected, or integral to; can be mechanically or electrically connected; the terms may be directly connected or indirectly connected through an intermediate, and may be communication between two elements or interaction relationship between two elements, unless otherwise specifically limited, and the specific meaning of the terms in the present invention will be understood by those skilled in the art according to specific situations.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A bidirectional-movement high-performance sliding window is characterized by comprising a window frame (1), a bidirectional-movement sliding sash frame (2), a multifunctional component (3) and an anti-resonance glass system (4) with different thicknesses.

2. The two-way moving high-performance sliding window according to claim 1, wherein the two-way moving sliding sash frame (2) and the multifunctional component (3) are respectively located inside the window frame (1), the unequal thickness anti-resonance glass system (4) is located inside the window frame (1) and the two-way moving sliding sash frame (2), the window frame (1) is composed of a plurality of aluminum alloy section bars I (5), the aluminum alloy section bars I (5) are in an end-to-end connection structure, one side of the aluminum alloy section bars I (5) is provided with a sash frame connecting clamping groove (6) and a multifunctional component connecting clamping groove (7), the sash frame connecting clamping groove (6) is connected with the two-way moving sliding sash frame (2) in a matching manner, and the multifunctional component connecting clamping groove (7) is connected with the multifunctional component (3) in a matching manner, the bidirectional moving push-pull fan frame (2) is composed of a plurality of fan frame units (11) and a bidirectional controller (12), the bidirectional controller (12) is connected between the fan frame units (11) and the window frame (1), the multifunctional component (3) is composed of a first water baffle (20), a second water baffle (21), a filter screen (22), a frame (23), a first pressing strip (24), a second pressing strip (25), a third pressing strip (26) and a fourth pressing strip (27), the first water baffle (20) and the second water baffle (21) are respectively connected to two sides of the frame (23), the filter screen (22) is positioned inside the first water baffle (20) and the second water baffle (21), the first pressing strip (24) and the second pressing strip (25) are respectively positioned on the side edges of two sides of the first water baffle (20), the third pressing strip (26) and the fourth pressing strip (27) are respectively positioned on the side edges of two sides of the second water baffle (21), the variable-thickness anti-resonance glass system (4) is composed of a first double-glass hollow glass (28), a second double-glass hollow glass (29), a built-in sunshade component (30) and a glass supporting frame body (31), wherein the first double-glass hollow glass (28) and the second double-glass hollow glass (29) are fixedly connected to the inside of the glass supporting frame body (31), and the built-in sunshade component (30) is located between the first double-glass hollow glass (28) and the second double-glass hollow glass (29) and is fixedly connected with the glass supporting frame body (31); a central inner cavity (8) is formed in the aluminum alloy section I (5), a plurality of side inner cavities I (9) are formed in one side of the interior of the aluminum alloy section I (5), and a plurality of side inner cavities II (10) are formed in the other side of the interior of the aluminum alloy section I (5); the sash frame unit (11) is composed of a plurality of aluminum alloy section II (13), the aluminum alloy section II (13) is of an end-to-end connection structure, one side of the aluminum alloy section II (13) is provided with a glass system clamping assembly (14) matched with the anti-resonance glass system (4) with different thicknesses, and the inside of the aluminum alloy section II (13) is provided with a plurality of rectangular inner cavities (15); center inner chamber (8) side inner chamber one (9) side inner chamber two (10) with the inside of rectangle inner chamber (15) all fills respectively has syllable-dividing heat preservation inner core (16), syllable-dividing heat preservation inner core (16) comprises puigging (17), first thermal-insulated heat preservation (18) and the thermal-insulated heat preservation of second (19), first thermal-insulated heat preservation (18) are located one side of puigging (17), the thermal-insulated heat preservation of second (19) are located the opposite side of puigging (17), puigging (17) are honeycomb structure, puigging (17) with first thermal-insulated heat preservation (18) with the thermal-insulated heat preservation of second (19) are hot pressing connection structure.

3. The two-way moving high-performance sliding window according to claim 2, wherein the first pressing bar (24), the second pressing bar (25), the third pressing bar (26) and the fourth pressing bar (27) are all of U-shaped structure, and the first pressing bar (24), the second pressing bar (25), the third pressing bar (26) and the fourth pressing bar (27) are all of deformable structure.

4. The sliding window with high performance and capable of moving in two directions as claimed in claim 2, wherein the built-in sunshade assembly (30) is of a lifting folding structure, and both sides of the inside of the glass supporting frame body (31) are respectively provided with a driving regulator (32) which is matched and connected with the built-in sunshade assembly (30).

5. The bidirectional-movement high-performance sliding window according to claim 2, wherein a plurality of limiting slideways (33) are arranged at the bottom end inside the window frame (1), a plurality of movable rollers (34) matched with the limiting slideways (33) are arranged at the bottom end of the bidirectional-movement sliding window frame (2), the movable rollers (34) are matched and connected with the bidirectional-movement sliding window frame (2) through movable shafts (35), and the movable rollers (34) are made of stainless steel.

6. The sliding window with the bidirectional movement and the high performance as claimed in claim 2, wherein a pressurized air pump (36) is disposed at the bottom end of one side of the window frame (1), an air flow groove (37) communicated with the pressurized air pump (36) is disposed at the bottom end of the inside of the window frame (1), a plurality of air inflation grooves (38) communicated with the air flow groove (37) are formed at the top end of the air flow groove (37), a plurality of sliding sealing blocks (39) attached to the window frame (1) are disposed at the bottom end of the sliding sash frame (2), and an air pressure chamber (40) is formed between the sliding sealing blocks (39).

7. A two-way movable high-performance sliding window according to claim 8, characterized in that an electromagnetic valve (41) is arranged inside the air inflation groove (38), a plurality of infrared reflection sensors (42) are arranged on one side of the air inflation groove (38), and an infrared reflector (43) matched with the infrared reflection sensors (42) is arranged at the top end inside the air pressure chamber (40).