CN212507951U

CN212507951U - Internal inverted translation window structure

Info

Publication number: CN212507951U
Application number: CN202022032386.8U
Authority: CN
Inventors: 贺绍宝
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-16
Filing date: 2020-09-16
Publication date: 2021-02-09
Anticipated expiration: 2030-09-16

Abstract

The utility model discloses an interior formula translation window structure of falling, including the window form, the translation subassembly, go up coupling assembling, lower bearing subassembly and locking subassembly, the user can control the translation position of casement as required in order to adjust the size of windowing, the limit of the frame internal area size that does not receive the window frame of the size of windowing of casement, solve traditional translation window and must be the problem that the window frame design could satisfy the complete windowing of at least casement double area, greatly reduce the occupation of window frame on the wall, reduce trompil area and cost of labor on the wall, the casement windows with horizontal translation mode simultaneously, the casement is parallel and be close to the wall after windowing, the space is minimum occupy-place, and is very convenient to use.

Description

Internal inverted translation window structure

Technical Field

The utility model relates to a window structure, in particular to fall formula translation window structure in.

Background

The translation window that can fall in on the existing market, its window frame are as the slide rail, and the casement carries out horizontal translation along the window frame in order to reach the effect of windowing, and such structure needs to design the window frame for the twice of casement area, just can guarantee that the casement opens in order to reach the effect of windowing the ventilation, leads to the whole occupy-place of window frame very big like this, and the area of windowing receives the restriction of window frame area.

SUMMERY OF THE UTILITY MODEL

The present invention aims to solve at least one of the above-mentioned technical problems in the related art to a certain extent. Therefore, the utility model provides an interior formula of falling translation window structure can greatly save installation space.

In order to achieve the above purpose, the technical scheme of the utility model is as follows:

according to the utility model discloses an interior formula translation window structure of falling of first aspect embodiment, include: the window body comprises a window frame and a window sash; the translation assembly comprises a plurality of sections of slide rail strips which are sequentially connected with each other, and the translation assembly is arranged on the upper part and the lower part of the window sash; one end of the upper connecting assembly is hinged to the upper part of the window frame, and the other end of the upper connecting assembly is hinged to the translation assembly on the upper part of the window sash; one end of the lower supporting component is hinged to the lower part of the window frame, and the other end of the lower supporting component is hinged to the translation component on the lower part of the window sash; a locking assembly for locking the sash within the frame; when only one window sash is arranged, the frame inner accommodating area of the window frame is set to be the area capable of accommodating only one window sash.

According to the utility model discloses fall formula translation window structure in has following beneficial effect at least: the user can control the translation position of casement as required in order to adjust the size of windowing, the size of windowing of casement does not receive the restriction of the interior area size of frame of window frame, solve traditional translation window and must be the problem that at least casement twice area could satisfy the complete windowing with the window frame design, greatly reduce the occupation of window frame on the wall, reduce trompil area and cost of labor on the wall, the while casement windows with horizontal translation mode, the parallel just wall that is close to of back casement windows, the space occupation is minimum, high convenience is used.

According to some embodiments of the utility model, the locking subassembly includes hand piece, last linkage and first fastener, first fastener fixed mounting be in on the lateral wall in the window frame, hand piece installs on the casement, go up the linkage and follow the casement side is connected the top of hand piece, hand piece drives go up the linkage and reciprocate, go up be equipped with on the linkage with the dop of first fastener cooperation joint.

According to some embodiments of the present invention, the upper connection assembly comprises an upper connection rod and a middle connection rod hinged to each other, and a hinge shaft is provided at a hinge point of the upper connection rod and the middle connection rod; the translation component positioned at the upper part of the window sash is provided with a movable lock head, and the end part of the lock head is provided with a clamping position matched with the outer wall of the articulated shaft; the upper end of the upper linkage bar is connected with a brace, the brace extends upwards and bends towards the upper frame of the window frame, and the brace is linked with the lock head to drive the lock head to move transversely; a lower linkage strip is connected below the handle piece, and a second clamping piece which is matched and spliced with the bottom end of the lower linkage strip is arranged at the lower part of the window frame; the lower bearing assembly comprises a lower connecting rod and a supporting seat which are hinged with each other, and the supporting seat is fixedly arranged on the translation assembly at the lower part of the window sash.

According to the utility model discloses a some embodiments, the tapered end with be equipped with the lock box between the translation subassembly, be equipped with the pressure spring in the lock box, the tapered end with the pressure spring is connected.

According to some embodiments of the utility model, be equipped with the third fastener on the brace, be equipped with the spout on the lock box, the tapered end through a driving medium with the mutual joint of third fastener, the driving medium is followed the spout removes.

According to the utility model discloses a some embodiments, go up the connecting rod with be equipped with first helping hand subassembly between the window frame, first helping hand subassembly includes mount pad, turning block and runner, mount pad fixed mounting be in window frame upper portion, it connects through the pivot rotation to go up the connecting rod on the mount pad, the turning block rotates to be connected on going up the connecting rod, the curved surface laminating of runner is in on the curved surface of pivot, be equipped with in the turning block and act on spring on the runner curved surface.

According to some embodiments of the invention, the upper and lower support assemblies are made of aluminum.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic view of the present invention in a state of opening a window;

fig. 2 is a schematic view of the inner falling state of the present invention;

FIG. 3 is a schematic structural view of the internal components of the present invention in an inverted state;

FIG. 4 is a schematic view of the internal components of the present invention in the open position;

fig. 5 is a schematic view of an upper connection assembly of the present invention;

fig. 6 is a schematic view of the lower support assembly of the present invention;

fig. 7 is a schematic view of the translation assembly of the present invention.

Reference numerals: a window frame 100; a window sash 200; a translation assembly 300; a slide rail bar 310; an upper connecting member 400; a lower bearing assembly 500; a locking assembly 600; a handle member 610; an upper linkage bar 620; a first catch 630; a chuck 621; an upper link 410; an intermediate link 420; a hinge shaft 430; a lock head 700; a position-lock 710; a pull-tab 622; a lower linkage bar 640; a second catch 650; a lower link 510; a support base 520; a lock case 720; a third catch 631; a transmission member 721; a first power assist assembly 800; a mount 810; a turning block 820; a runner 830; a spring 840.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

As shown in fig. 1, an inverted window structure includes a window body, a translation assembly 300, an upper connection assembly 400, a lower support assembly 500, and a locking assembly 600. The window includes a frame 100 and a sash 200, and in the present embodiment, one sash 200 is provided as an example. The frame receiving area of the window frame 100 is an area of one window sash 200. The translation assembly 300 includes a plurality of sections connected to the slide rail bar 310 in sequence, as shown in fig. 7, the slide rail bar 310 is provided in three sections, when the translation assembly 300 is in the folded state, the three sections of the slide rail bar 310 are overlapped, and when the translation assembly 300 is in the working state, the three sections of the slide rail bar 310 are sequentially pulled apart to be integrally stretched in the transverse direction. A translation assembly 300 is installed at both upper and lower portions of the window sash 200. An upper connecting assembly 400 is installed between the translational assembly 300 positioned at the upper portion of the window sash 200 and the upper portion of the window frame 100, and as shown in fig. 5, two upper connecting assemblies 400 may be provided in parallel with each other, one end of each upper connecting assembly 400 is hinged to the upper portion of the window frame 100, and the other end thereof is hinged to the translational assembly 300 positioned at the upper portion of the window sash 200. A lower bearing assembly 500 is installed between the translational assembly 300 at the lower portion of the window sash 200 and the lower portion of the window frame 100. as shown in fig. 6, the connecting assembly may be provided with two lower bearing assemblies 500 parallel to each other, the lower bearing assemblies 500 being hinged at one end to the lower portion of the window frame 100 and at the other end to the translational assembly 300 at the lower portion of the window sash 200.

When the window sash 200 is in the closed state in the window frame 100, the translational assemblies 300 at the upper and lower portions of the window sash 200 are simultaneously in the collapsed state, and the window sash 200 is locked in the window frame 100 by the locking assembly 600. As shown in fig. 1, when the window needs to be opened, the locking assembly 600 is opened, and the upper and lower portions of the window sash 200 are simultaneously pulled out from the window frame 100 in the indoor direction by the hinge action of the upper connecting assembly 400 and the lower supporting assembly 500, and then the window sash 200 is laterally moved, at which time the sliding rails of the translation assembly 300 are changed from the retracted state to the extended state. The user can control the translation position of casement 200 as required in order to adjust the size of windowing, the size of windowing of casement 200 does not receive the restriction of the interior area size of frame of window frame 100, solve traditional translation window and must be the problem that at least 200 double areas of casement could satisfy the complete windowing with window frame 100 design, greatly reduce the occupation of window frame 100 on the wall, open area and cost of labor on the reduction wall, casement 200 windows with horizontal translation mode simultaneously, window back casement 200 is parallel and be close to the wall, the minimum occupation of space, high convenience is brought to use.

As shown in fig. 4, in some embodiments of the present invention, the locking assembly 600 includes a handle 610, an upper linkage strip 620 and a first fastener 630, the first fastener 630 is fixedly installed on the side wall inside the window frame 100, the handle 610 is installed on the window sash 200, the upper linkage strip 620 is connected along the side edge of the window sash 200 above the handle 610, the handle 610 drives the upper linkage strip 620 to move up and down, and the upper linkage strip 620 is provided with a clamp 621 engaged with the first fastener 630 in a matching manner. The lower end of the upper linkage strip 620 is connected with the handle part 610, the upper linkage strip 620 can be driven to move up and down along the side edge of the window sash 200 when the handle part 610 is rotated, and the clamping head 621 on the upper linkage strip 620 is driven to move in the process of moving up and down, so that whether the clamping head 621 is clamped on the first clamping piece 630 or not is controlled, and opening and closing of the window sash 200 are controlled.

As shown in fig. 3 and 4, in some embodiments of the present invention, the upper connecting assembly 400 includes an upper link 410 and an intermediate link 420 hinged to each other, and a hinge shaft 430 is provided at the hinge of the upper link 410 and the intermediate link 420; a movable lock head 700 is arranged on the translation assembly 300 positioned at the upper part of the window sash 200, and a clamping position 710 matched with the outer wall of the hinge shaft 430 is arranged at the end part of the lock head 700; a brace 622 is connected to the upper end of the upper linkage bar 620, the brace 622 extends upwards and bends towards the upper frame of the window frame 100, and the brace 622 is linked with the lock head 700 to drive the lock head 700 to move transversely; a lower linkage strip 640 is connected below the handle piece 610, and a second clamping piece 650 which is matched and inserted with the bottom end of the lower linkage strip 640 is arranged at the lower part of the window frame 100; the lower bearing assembly 500 includes a lower link 510 and a bearing 520 hinged to each other, and the bearing 520 is fixedly installed on the translation assembly 300 at the lower portion of the window sash 200.

When the window sash 200 is switched from the closed state to the fully open state as shown in fig. 1 and 4, the handle member 610 is rotated 90 degrees counterclockwise, the chuck 621 leaves the first latch 630, the lower link strip 640 moves upward and leaves the second latch 650, the latch 710 on the lock head 700 is latched on the hinge shaft 430 at this time, the movement of the middle link 420 is limited, the window sash 200 is pulled towards the indoor direction, and the upper link 410 and the lower link 510 swing to enable the window sash 200 to be integrally pulled out and then to be translated.

As shown in fig. 2 and 3, the operating state of the window sash 200 is a tilt-in state of being opened upward and closed downward. The window sash 200 is converted into an inward-falling state from a closed state, when the window sash 200 is in a completely closed state, the middle connecting rod 420 is parallel to the long edge direction of the sliding rail strip 310, the handle piece 610 is rotated 180 degrees anticlockwise, the upper linkage strip 620 drives the clamping head 621 to leave the first clamping piece 630, at the moment, the pulling strip 622 moves rightwards to drive the clamping position 710 of the locking head 700 to leave the upper connecting rod 410 and the hinge shaft 430 of the middle connecting rod 420, the movement limitation on the middle connecting rod 420 is removed, at the moment, the lower linkage strip 640 moves downwards, and the bottom end of the lower linkage strip 640 is inserted into the second clamping piece 650. When the window sash 200 is pulled toward the indoor direction, the upper link 410 and the middle link 420 rotate around the hinge point thereof to unfold, so that the upper portion of the window sash 200 leaves the window frame 100, and at the same time, the lower link 640 is inserted into the second latch, so that the movement of the lower portion of the window sash 200 leaving the window frame 100 is limited, and the support 520 rotates around the hinge point with the lower link 510, so that the window sash 200 is switched from the fully closed state to the inverted state.

As shown in fig. 3, in some embodiments of the present invention, a lock box 720 is disposed between the lock head 700 and the translation assembly 300, a pressure spring (not shown in the figure) is disposed in the lock box 720, and the lock head 700 is connected to the pressure spring. The elastic deformation of the pressure spring is used for controlling the automatic reset of the lock head 700 after the movement. The brace 622 is provided with a third clamping piece 631, the lock box 720 is provided with a sliding groove, the lock head 700 is clamped with the third clamping piece 631 through a transmission piece 721, and the transmission piece 721 moves along the sliding groove. The brace 622 drives the lock head 700 to move through the third clamping piece 631 and the transmission piece 721 when moving, and meanwhile, the sliding groove is used for transversely guiding the moving direction of the transmission piece 721, so that the moving stability of the lock head 700 is guaranteed.

As shown in fig. 5, in some embodiments of the present invention, a first assisting component 800 is disposed between the upper connecting rod 410 and the window frame 100, the first assisting component 800 includes a mounting seat 810, a rotating block 820 and a rotating wheel 830, the mounting seat 810 is fixedly mounted on the upper portion of the window frame 100, the upper connecting rod 410 is rotatably connected to the mounting seat 810 through a rotating shaft, the rotating block 820 is rotatably connected to the upper connecting rod 410, a curved surface of the rotating wheel 830 is attached to a curved surface of the rotating shaft, and a spring 840 acting on the curved surface of the rotating wheel 830 is disposed in the rotating block 820. As shown in fig. 5, the three points of the position of the rotating shaft, the point of the connecting block 820 with the upper link 410, and the point of the rotating wheel 830 and the rotating shaft fitting the curved surface form a triangular distribution in space. When the window sash 200 is pulled out from the window frame 100, the upper connecting rod 410 rotates around the rotating shaft and drives the rotating block 820 to move, at the moment, the rotating wheel 830 is attached to the curved surface of the rotating shaft to rotate, the position point of the rotating shaft, the point where the rotating block 820 is connected with the upper connecting rod 410, and the point where the rotating wheel 830 is attached to the curved surface of the rotating shaft are changed in distribution of a triangle formed in space, the elastic action force of the spring 840 is utilized to act on the rotating wheel 830 in the changing process, the upper connecting rod 410 has an assisting effect on the opening direction of the window sash 200, and the opening process is very labor-saving.

The contrast uses the subassembly that the die-casting formed on the market, and the material of going up coupling assembling 400 and lower bearing subassembly 500 is the aluminum product, through the sheet metal component shaping, guarantees structural strength, and easy to assemble and change.

In the description herein, references to the description of a particular embodiment or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims

1. An interior formula translation window structure that falls, includes:

the window comprises a window frame (100) and a window sash (200);

the translation assembly (300) comprises a plurality of sections of slide rail bars (310) which are sequentially connected with each other, and the translation assembly (300) is arranged at the upper part and the lower part of the window sash (200);

an upper connecting assembly (400), one end of the upper connecting assembly (400) is hinged on the upper part of the window frame (100), and the other end of the upper connecting assembly (400) is hinged on the translation assembly (300) on the upper part of the window sash (200);

a lower bearing assembly (500), one end of the lower bearing assembly (500) is hinged on the lower part of the window frame (100), and the other end of the lower bearing assembly (500) is hinged on the translation assembly (300) on the lower part of the window sash (200);

a locking assembly (600) for locking the sash (200) within the frame (100);

wherein, when only one window sash (200) is provided, the frame-inside accommodation area of the window frame (100) is set to an area that can accommodate only one window sash (200).

2. The inverted translating window structure of claim 1 wherein: locking subassembly (600) include handle spare (610), go up linkage strip (620) and first fastener (630), first fastener (630) fixed mounting be in on the lateral wall in window frame (100), install handle spare (610) on casement (200), it follows to go up linkage strip (620) casement (200) side is connected the top of handle spare (610), handle spare (610) drive go up linkage strip (620) and reciprocate, go up be equipped with on linkage strip (620) with dop (621) of first fastener (630) cooperation joint.

3. The inverted translating window structure of claim 2 wherein:

the upper connecting assembly (400) comprises an upper connecting rod (410) and an intermediate connecting rod (420) which are hinged with each other, and a hinge shaft (430) is arranged at the hinged position of the upper connecting rod (410) and the intermediate connecting rod (420);

a movable lock head (700) is arranged on the translation assembly (300) positioned at the upper part of the window sash (200), and a clamping position (710) matched with the outer wall of the hinge shaft (430) is arranged at the end part of the lock head (700);

the upper end of the upper linkage bar (620) is connected with a brace (622), the brace (622) extends upwards and bends towards the upper side frame of the window frame (100), and the brace (622) is linked with the lock head (700) to drive the lock head (700) to move transversely;

a lower linkage strip (640) is connected below the handle piece (610), and a second clamping piece (650) which is matched and spliced with the bottom end of the lower linkage strip (640) is arranged at the lower part of the window frame (100);

the lower bearing assembly (500) comprises a lower connecting rod (510) and a supporting seat (520) which are hinged with each other, and the supporting seat (520) is fixedly arranged on the translation assembly (300) at the lower part of the window sash (200).

4. The inverted translating window structure of claim 3 wherein: the lock head (700) and be equipped with between translation subassembly (300) lock box (720), be equipped with the pressure spring in the lock box (720), lock head (700) with the pressure spring is connected.

5. The inverted translating window structure of claim 4 wherein: be equipped with third fastener (631) on brace (622), be equipped with the spout on lock box (720), tapered end (700) through a driving piece (721) with third fastener (631) joint each other, driving piece (721) are followed the spout removes.

6. The inverted translating window structure of claim 3 wherein: go up connecting rod (410) with be equipped with first helping hand subassembly (800) between window frame (100), first helping hand subassembly (800) include mount pad (810), turning block (820) and runner (830), mount pad (810) fixed mounting in window frame (100) upper portion, go up connecting rod (410) rotate through the pivot and connect on mount pad (810), turning block (820) rotate and connect on going up connecting rod (410), the curved surface laminating of runner (830) is in on the curved surface of pivot, be equipped with in turning block (820) and act on spring (840) on runner (830) curved surface.

7. The inverted translating window structure of claim 1 wherein: the upper connecting assembly (400) and the lower supporting assembly (500) are made of aluminum materials.