CN222668019U - Low-energy-consumption aluminum alloy combined door and window - Google Patents

Abstract

The utility model relates to the technical field of door and window design, and discloses a low-energy-consumption aluminum alloy combined door and window, which comprises a fixed frame and a window, wherein a sliding rail is arranged in the fixed frame, a pulley corresponding to the sliding rail is arranged at the bottom of the window, a control component for controlling a locking block is arranged in a locking cavity, and the locking block and a locking groove are arranged to ensure that the window is firmly sealed when closed, so that air exchange is effectively prevented, energy consumption is reduced, locking or unlocking of the window can be realized through clockwise or anticlockwise rotation of the control button, the operation is simple and convenient, the use convenience is improved, a driving screw rod can be effectively fixed through the arrangement of a fixed ring, the possibility of looseness or dislocation is reduced, the reliability and stability of an integral system are improved, and the frequency of using a heater or an air conditioner can be reduced, the energy consumption is reduced through the reduction of indoor and the outdoor air exchange, and the energy-saving and environment-friendly effects are achieved.

Description

Low-energy-consumption aluminum alloy combined door and window

Technical Field

The utility model relates to the technical field of doors and windows, in particular to a low-energy-consumption aluminum alloy combined door and window.

Background

Sectional doors and windows generally refer to door and window products that are composed of a combination of a plurality of different materials or design elements. These sectional doors and windows may include combinations of materials such as wood, aluminum alloys, plastics, or the like, or incorporate different types of glass such as insulating glass, safety glass, and the like. The design can meet the diversified demands of users on doors and windows, such as improving heat preservation performance, enhancing safety, improving decorative effect and the like.

Most sliding rail type windows in the prior art can sometimes have gaps when being closed in a sliding way, so that indoor and outdoor air exchange is caused, more heating is needed in a cold season, more air conditioners are needed in a hot season to maintain indoor temperature, and energy consumption is increased, therefore, the existing requirements are not met, and the aluminum alloy combined type door and window with low energy consumption is provided.

Disclosure of utility model

The utility model provides a low-energy-consumption aluminum alloy combined door and window, which has the beneficial effect of ensuring that the window is firmly sealed when being closed, and solves the problems that most of existing sliding rail type windows in the background art can sometimes have gaps when being closed in a sliding way, so that indoor and outdoor air exchange is caused, more heating is needed in a cold season, more air conditioners are needed in a hot season to maintain the indoor temperature, and the energy consumption is increased.

The utility model provides a low-energy-consumption aluminum alloy combined door and window, which comprises a fixed frame and a window, wherein a sliding rail is arranged in the fixed frame, a pulley corresponding to the sliding rail is arranged at the bottom of the window, the pulley of the window is slidably arranged on the sliding rail of the fixed frame, a locking cavity is formed in the fixed frame, a locking block is arranged in the locking cavity, a locking groove corresponding to the locking block is formed in the window, the locking block and the locking groove are opened and closed when the window is closed, and a control assembly for controlling the locking block is arranged in the locking cavity.

As an alternative scheme of the low-energy-consumption aluminum alloy combined door and window, the control assembly comprises a fixed block fixedly arranged on the side part of the locking block, a control rod is arranged at the bottom of the fixed block, a driving ring is arranged at the bottom end of the control rod, a driving screw rod is inserted into the driving ring, the driving screw rod is arranged to be a bidirectional screw rod, an inner threaded ring corresponding to the driving screw rod is arranged in the driving ring, and the driving ring is sleeved on the driving screw rod in a sliding manner through the inner threaded ring.

As an alternative scheme of the low-energy-consumption aluminum alloy combined door and window, the fixed frame is provided with the rotating groove, the driving screw rod is connected with the control button through the rotating groove, and the control button is used for driving the driving screw rod.

As an alternative scheme of the low-energy-consumption aluminum alloy combined door and window, a fixing ring used for fixing the driving screw rod is arranged in the locking cavity, the fixing ring is sleeved on the driving screw rod far away from the driving ring, and the number of the fixing rings is two.

As an alternative scheme of the low-energy-consumption aluminum alloy combined door and window, a groove is formed in the locking cavity, the groove is communicated with the locking cavity, an auxiliary rod is fixedly arranged on the rear side of the fixing block, and the auxiliary rod is inserted into the groove.

As an alternative scheme of the low-energy-consumption aluminum alloy combined door and window, the end part of the auxiliary rod is rotatably provided with an auxiliary gear, an auxiliary rack corresponding to the auxiliary gear is arranged in the groove, and the auxiliary gear is meshed with the auxiliary rack.

As an alternative scheme of the low-energy-consumption aluminum alloy combined door and window, a bearing is arranged in the rotary groove, and the bearing is sleeved outside the driving screw rod.

As an alternative scheme of the low-energy-consumption aluminum alloy combined type door and window, the locking blocks and the control assembly are arranged in two groups, the locking blocks and the control assembly are symmetrically arranged in the locking cavity, glass is arranged in the window, three glass assemblies are arranged, and sealing rubber strips are arranged on the three glass assemblies.

The utility model has the following beneficial effects:

1. This low energy consumption aluminum alloy combination formula door and window for guarantee that the window is firmly sealed when closing through the setting of locking piece and locking groove, thereby effectively prevent air exchange, reduce energy consumption, clockwise or anticlockwise rotation through the control button, alright lock or the unblock of realizing the window, easy operation is convenient, use convenience has been improved, through the setting of solid fixed ring, make effectively fixed drive lead screw, reduce not hard up or dislocation's possibility, reliability and stability of whole system have been improved, through reducing indoor outer air exchange, make can reduce the frequency of using the heater or air conditioner, reduce energy consumption, reach energy-concerving and environment-protective effect.

2. This low energy consumption aluminum alloy combination formula door and window through the design that adds auxiliary rod and auxiliary gear for can realize more stable and accurate operation control, thereby improved opening and locking effect of window, through having strengthened the symmetry setting of locking piece and control assembly, and the design that glass subassembly installed joint strip, make further strengthen the sealing performance of window, effectively prevent air exchange, reduce energy consumption.

Drawings

Fig. 1 is a schematic perspective view of a main body of the present utility model.

Fig. 2 is a schematic view of a cut-away structure of a main body of the present utility model.

Fig. 3 is an enlarged schematic view of the structure of the present utility model at a.

Fig. 4 is a schematic side view in cross-section of the present utility model.

Fig. 5 is a schematic diagram of a further side view in cross-section of the present utility model.

Fig. 6 is a schematic view of another planar structure of the present utility model.

100 Parts of fixed frames, 110 parts of sliding rails, 120 parts of locking grooves, 130 parts of rotating grooves, 131 parts of bearings, 200 parts of windows, 210 parts of pulleys, 220 parts of locking cavities, 230 parts of locking blocks, 240 parts of fixed rings, 250 parts of grooves, 251 parts of auxiliary racks, 260 parts of glasses, 261 parts of sealing rubber strips, 300 parts of control components, 310 parts of fixed blocks, 320 parts of control rods, 321 parts of driving rings, 322 parts of internal thread rings, 330 parts of driving screw rods, 331 parts of control buttons, 340 parts of auxiliary rods, 341 parts of auxiliary gears.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In a first embodiment, the present embodiment is intended to facilitate solving the problem that most of existing sliding rail 110 type windows 200 may have gaps when sliding and closing, resulting in indoor and outdoor air exchange, so that more heating is required in cold seasons, more air conditioning is required in hot seasons to maintain indoor temperature, and energy consumption is increased, referring to fig. 1-6, a low energy consumption aluminum alloy combined type door and window comprises a fixed frame 100 and a window 200, wherein the sliding rail 110 is installed in the fixed frame 100, the pulley 210 corresponding to the sliding rail 110 is installed at the bottom of the window 200, the pulley 210 of the window 200 is slidably installed on the sliding rail 110 of the fixed frame 100, the locking cavity 220 is formed in the fixed frame 100, the locking block 230 is arranged in the locking cavity 220, the locking groove 120 corresponding to the locking block 230 is formed in the window 200, the locking block 230 and the locking groove 120 are opened and closed when the window 200 is closed, and the control assembly 300 for controlling the locking block 230 is arranged in the locking cavity 220.

The control assembly 300 comprises a fixed block 310 fixedly arranged at the side part of the locking block 230, a control rod 320 is arranged at the bottom of the fixed block 310, a driving ring 321 is arranged at the bottom end of the control rod 320, a driving screw rod 330 is inserted into the driving ring 321, the driving screw rod 330 is arranged as a bidirectional screw rod, an internal thread ring 322 corresponding to the driving screw rod 330 is arranged in the driving ring 321, and the driving ring 321 is sleeved on the driving screw rod 330 in a sliding manner through the internal thread ring 322. The fixed frame 100 is provided with a rotary slot 130, the driving screw 330 is connected with a control button 331 through the rotary slot 130, and the control button 331 is used for driving the driving screw 330. A fixing ring 240 for fixing the driving screw rod 330 is arranged in the locking cavity 220, the fixing ring 240 is sleeved on the driving screw rod 330 far away from the driving ring 321, and the number of the fixing rings 240 is two.

When the window 200 is driven to be closed by sliding the pulley 210 on the sliding rail 110, the side wall of the window 200 is embedded into the fixed frame 100, and then the control button 331 is rotated clockwise to drive the driving screw 330 to rotate, and the driving screw 330 is provided with a bidirectional screw along with the rotation of the driving screw 330, so that the driving screw 330 is matched with the driving ring 321 in a threaded manner, the fixed block 310 drives the locking block 230 to gather towards the window 200, so that the locking block 230 is opened and closed with the locking groove 120 on the window 200, and the window 200 is locked.

When the window 200 needs to be opened, the control button 331 is rotated anticlockwise, the driving screw 330 is driven to rotate anticlockwise, and the locking block 230 is driven to move to two sides along with the rotation of the driving screw 330, so that the window 200 is unlocked from the locking groove 120, and then the window 200 is pulled to be opened.

In the embodiment, the locking block 230 and the locking groove 120 are arranged, so that the window 200 is firmly sealed when being closed, air exchange is effectively prevented, energy consumption is reduced, locking or unlocking of the window 200 can be realized through clockwise or anticlockwise rotation of the control button 331, operation is simple and convenient, use convenience is improved, the screw rod 330 can be effectively fixed and driven through the arrangement of the fixing ring 240, loosening or dislocation possibility is reduced, reliability and stability of the whole system are improved, frequency of using a heater or an air conditioner can be reduced through reduction of indoor and outdoor air exchange, energy consumption is reduced, and energy saving and environment protection effects are achieved.

In the second embodiment, the present embodiment is intended to facilitate solving the problem that the overall sealing performance and operation may be less stable, and the present embodiment is an improvement made on the basis of the first embodiment, and in particular, refer to fig. 1 to 6.

The locking cavity 220 is provided with a groove 250, the groove 250 is communicated with the locking cavity 220, the rear side of the fixed block 310 is fixedly provided with an auxiliary rod 340, and the auxiliary rod 340 is inserted into the groove 250. An auxiliary gear 341 is rotatably installed at an end of the auxiliary lever 340, an auxiliary rack 251 corresponding to the auxiliary gear 341 is provided in the recess 250, and the auxiliary gear 341 is engaged with the auxiliary rack 251.

The rotary groove 130 is internally provided with a bearing 131, and the bearing 131 is sleeved outside the driving screw rod 330. The locking blocks 230 and the control assembly 300 are arranged in two groups, the locking blocks 230 and the control assembly 300 are symmetrically arranged in the locking cavity 220, glass 260 is arranged in the window 200, the number of the glass 260 is three, and sealing rubber strips 261 are arranged on the three glass 260 assemblies.

In this embodiment, by adding the auxiliary lever 340 and the auxiliary gear 341, more stable and precise operation control can be achieved, thereby improving the opening and locking effects of the window 200, and by reinforcing the symmetrical arrangement of the locking block 230 and the control assembly 300, and the design of the glass 260 assembly with the sealing rubber strip 261, the sealing performance of the window 200 is further enhanced, air exchange is effectively prevented, and energy consumption is reduced.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that it will be apparent to those skilled in the art that several modifications and variations can be made without departing from the technical principle of the present utility model, and these modifications and variations should also be regarded as the scope of the utility model.

Claims (8)

1. The utility model provides a low energy consumption aluminum alloy combination formula door and window, includes fixed frame (100) and window (200), wherein install slide rail (110) in fixed frame (100), window (200) bottom install with pulley (210) corresponding to slide rail (110), pulley (210) slidable mounting of window (200) are in on slide rail (110) of fixed frame (100), set up locking chamber (220) in fixed frame (100), be provided with locking piece (230) in locking chamber (220), set up on window (200) with locking groove (120) corresponding to locking piece (230), when window (200) are closed locking piece (230) with locking groove (120) open and shut, be provided with in locking chamber (220) and be used for controlling control subassembly (300) of locking piece (230).

2. The low-energy-consumption aluminum alloy combined door and window according to claim 1, wherein the control assembly (300) comprises a fixed block (310) fixedly installed on the side portion of the locking block (230), a control rod (320) is installed at the bottom of the fixed block (310), a driving ring (321) is installed at the bottom end of the control rod (320), a driving screw (330) is inserted into the driving ring (321), the driving screw (330) is arranged to be a bidirectional screw, an inner threaded ring (322) corresponding to the driving screw (330) is arranged in the driving ring (321), and the driving ring (321) is sleeved on the driving screw (330) in a sliding mode through the inner threaded ring (322).

3. The aluminum alloy combined door and window with low energy consumption according to claim 2, wherein the fixed frame (100) is provided with a rotary groove (130), the driving screw rod (330) is connected with a control button (331) through the rotary groove (130), and the control button (331) is used for driving the driving screw rod (330).

4. The aluminum alloy combined door and window with low energy consumption according to claim 3, wherein a fixing ring (240) for fixing the driving screw rod (330) is arranged in the locking cavity (220), the fixing ring (240) is sleeved on the driving screw rod (330) far away from the driving ring (321), and the number of the fixing rings (240) is two.

5. The aluminum alloy combined door and window with low energy consumption according to claim 2, wherein the locking cavity (220) is internally provided with a groove (250), the groove (250) is communicated with the locking cavity (220), an auxiliary rod (340) is fixedly arranged at the rear side of the fixed block (310), and the auxiliary rod (340) is inserted into the groove (250).

6. The aluminum alloy combined door and window with low energy consumption according to claim 5, wherein an auxiliary gear (341) is rotatably installed at the end of the auxiliary rod (340), an auxiliary rack (251) corresponding to the auxiliary gear (341) is arranged in the groove (250), and the auxiliary gear (341) is meshed with the auxiliary rack (251).

7. The aluminum alloy combined door and window with low energy consumption according to claim 3, wherein a bearing (131) is arranged in the rotary groove (130), and the bearing (131) is sleeved outside the driving screw rod (330).

8. The aluminum alloy combined door and window with low energy consumption according to claim 1, wherein the locking blocks (230) and the control assembly (300) are arranged in two groups, the locking blocks (230) and the control assembly (300) are symmetrically arranged in the locking cavity (220), glass (260) is arranged in the window (200), the number of the glass (260) is three, and sealing rubber strips (261) are arranged in the three glass (260) assemblies.