CN112343458A - Efficient door and window installation method - Google Patents

Abstract

The application relates to the field of door and window installation, in particular to a high-efficiency door and window installation method. The key points of the technical scheme are as follows: the method comprises the following steps: s1: the locking mechanism is started to test the operation fluency of the locking mechanism; s2: installing a locking frame, and embedding the locking frame into a window opening of a building; s3: installing a door and window body, covering and positioning the door and window body into the locking frame along the vertical direction, starting a locking mechanism on the locking frame, and locking and fixing the periphery of the door and window body by the locking mechanism; s4: the installation stability of inspection door and window body is tested and accepted, and this application has the effect that promotes door and window's installation effectiveness.

Description

Efficient door and window installation method

Technical Field

The application relates to the field of door and window installation, in particular to a high-efficiency door and window installation method.

Background

The door and window is an important component in the building, and in terms of the action effect of the door and window, on one hand, the door and window can perform the temperature control effects of heat insulation and heat preservation on the indoor space of the building, reduce the starting time of an indoor air conditioner and play a role in energy conservation and environmental protection; on the other hand, the door and window also has the functions of ventilation and lighting, so that the ventilation of indoor air is facilitated, and the health of residents is facilitated.

At present, the door and window mainly comprises a window frame and a window sash rotatably installed in the window frame, and when the door and window are installed, the window frame of the door and window is usually required to be driven into a window opening side wall reserved in a building through expansion screws so as to realize the fixed installation of the window frame.

To the correlation technique among the above-mentioned, at the in-process of installing the window frame, the window frame sets up a plurality of fixed point positions mutually with the building on circumferential direction usually to stability when guaranteeing the window frame installation, consequently need consolidate the installation to a plurality of inflation screws, the installation is comparatively loaded down with trivial details, and the installation effectiveness is comparatively low.

Disclosure of Invention

In order to improve the installation efficiency of doors and windows, the application provides a high-efficiency door and window installation method.

The application provides a high-efficient door and window mounting method adopts following technical scheme: a high-efficiency door and window installation method comprises the following steps:

s1: the locking mechanism is started to test the operation fluency of the locking mechanism;

s2: installing a locking frame, and embedding the locking frame into a window opening of a building;

s3: installing a door and window body, covering and positioning the door and window body into the locking frame along the vertical direction, starting a locking mechanism on the locking frame, and locking and fixing the periphery of the door and window body by the locking mechanism;

s4: and (5) checking the installation stability of the door and window body, and checking and accepting.

Through adopting above-mentioned technical scheme, at the in-process of installing the door and window body, only need to close the door and window body lid to pre-buried locking frame department to the building in, start locking mechanism immediately for the door and window body obtains locking, finally realizes the installation of door and window body, and installation convenient and fast, the installation effectiveness of door and window body obtains promoting.

Preferably, the installation method adopts the following installation structure, including a locking frame, a locking mechanism and a door and window body; the locking frame comprises a first frame body and a plurality of embedded fixing pieces arranged along the periphery of the first frame body, and the embedded fixing pieces are used for being embedded into a building; the locking mechanism comprises a power input assembly, a transmission assembly and a clamping assembly; the clamping components are rotationally connected to the locking frame, the clamping components are multiple and are uniformly arranged along the peripheral direction of the locking frame, the door and window body is covered and positioned in the locking frame, a plurality of locking grooves are formed in the peripheral edge of the door and window body, and the clamping components are rotationally buckled in the locking grooves; the transmission assembly is rotationally connected to the locking frame, the transmission assembly is arranged around the peripheral direction of the locking frame, the transmission assembly is sequentially connected with the clamping assemblies, and the transmission assembly is used for transmitting torque to the clamping assemblies so as to enable the clamping assemblies to rotate; the power input assembly is rotatably connected in the locking frame and is connected with the transmission assembly, and the power input assembly 21 is used for inputting torque to the transmission assembly so as to drive the clamping assembly to rotate.

Through adopting above-mentioned technical scheme, start the power input subassembly, the power input subassembly is with moment of torsion input to transmission assembly department, transmission assembly who arranges around closure frame circumferencial direction transmits the moment of torsion to evenly arranging on a plurality of joint subassemblies on the closure frame circumferencial direction, joint subassembly rotates the lock to the locking groove of door and window body this moment, the door and window body obtains the multiple spot location on the circumferential direction, the door and window body realizes that the closure is fixed, can drive a plurality of joint subassemblies through power input once and lock the door and window body, process convenient and fast, the installation effectiveness is high.

Preferably, the power input assembly comprises a worm wheel, a worm and a hand wheel, the worm is rotationally connected to the inside of the locking frame, the worm wheel is fixedly connected to the transmission assembly, the hand wheel is fixedly connected to the worm, and the worm wheel is meshed with the worm.

Through adopting above-mentioned technical scheme, through gripping the hand wheel and rotating the hand wheel, the hand wheel can drive the worm and rotate, and the worm is at the rotation in-process, rotates with the worm wheel that the worm meshes mutually is corresponding, and turbine drive assembly realizes rotating, and then realizes the input of moment of torsion in drive assembly department, and the process is swift convenient, and the controllability is strong, in addition, turbine and worm possess self-locking function when mutual interlock, so can make the structure realize the locking under conventional state, and the overall stability of structure obtains promoting.

Preferably, the transmission assembly comprises a plurality of main transmission parts and a plurality of sub transmission parts; the main transmission parts are rotatably connected to the locking frame, the main transmission parts are arranged in a surrounding mode along the circumferential direction of the locking frame, the main transmission parts are sequentially connected end to end, and the power input assembly is connected with any one of the main transmission parts; the sub-transmission parts are arranged in a surrounding mode along the circumferential direction of the locking frame and are respectively connected with the main transmission part and the clamping assembly.

Through adopting above-mentioned technical scheme, the moment of torsion of power input subassembly department input orders about arbitrary initiative transmission portion and rotates, the initiative transmission portion that links to each other with the power input subassembly transmits the moment of torsion to all the other initiative transmission portions in proper order afterwards, a plurality of initiative transmission portion rotates simultaneously this moment, here, encircle to arrange and realize rotating in a plurality of sub-transmission portions of closure frame circumference direction, a plurality of sub-transmission portions correspond a plurality of joint subassemblies of drive and rotate simultaneously, realize the lock of door and window body in the ascending while of circumference direction, the process is swift convenient.

Preferably, the main transmission part includes first connecting shafts and first bevel gears, the first bevel gears are respectively and fixedly connected to two ends of the first connecting shafts, two first bevel gears on any two adjacent first connecting shafts are engaged with each other, and the first connecting shafts are respectively connected with the sub transmission part and the power input part.

By adopting the technical scheme, the power input part drives any first connecting shaft to rotate, the first connecting shafts rotate simultaneously under the transmission association of the first bevel gears, and at the moment, the torque can be input to the sub-transmission parts by the first connecting shafts.

Preferably, the sub-transmission part comprises a second bevel gear, and the second bevel gear is respectively and fixedly connected to the main transmission part and the clamping component and is respectively and fixedly arranged on the main transmission part and two second bevel gears on the clamping component to be mutually meshed.

Through adopting above-mentioned technical scheme, the bevel gear of two mutual interlocks can be shunted the moment of torsion to joint subassembly department, and the structure is practical.

Preferably, the clamping assembly comprises a second connecting shaft, a sliding clamping block and a tension spring; the second connecting shaft is rotatably connected to the locking frame and is connected with the transmission assembly; the sliding clamping block is connected to the second connecting shaft in a sliding mode along the length direction of the second connecting shaft; the tension spring is respectively fixed with the sliding clamping block and the locking frame; the clamp splice that slides with the locking groove is relative, the second connecting axle is used for the drive the clamp splice that slides rotates the lock extremely in the locking groove, one side cell wall in locking groove has slope section and joint section, the clamp splice that slides rotate the lock extremely the in-process in the locking groove, the clamp splice that slides in proper order with slope section and the butt that slides of joint section, work as the clamp splice that slides with during joint section butt, the extension spring is tensile form setting.

Through adopting above-mentioned technical scheme, at the in-process of joint subassembly joint to closure inslot, the clamp splice that slides in proper order with the slope section and the joint section butt in closure groove, the clamp splice that slides this moment slides on the second connecting axle to stretch the extension spring, when the clamp splice that slides removes to the joint section, the extension spring applys elasticity to the clamp splice that slides, the clamp splice that slides and the cell wall laminating butt in closure groove, the clamp splice that slides this moment is fixed with door and window body lock, the structure is firm.

Preferably, the clamping assembly further comprises a limiting block, the limiting block is fixedly connected to the second connecting shaft, and the limiting block is abutted and limited by the sliding clamping block.

Through adopting above-mentioned technical scheme, the stopper carries on spacingly to the clamp splice that slides for difficult pine takes off outside the second connecting axle when the clamp splice that slides, and the structure is practical.

Preferably, the embedded fixing member includes a first reinforcing plate and a second reinforcing plate, a side edge of the first reinforcing plate is fixedly connected to the locking frame, the second reinforcing plate is fixedly connected to the other side of the first reinforcing plate, and the first reinforcing plate and the second reinforcing plate are perpendicular to each other.

Through adopting above-mentioned technical scheme, first gusset plate and second gusset plate form the lock structure of T font, with pre-buried mounting embedding to the building in, can realize carrying out the lock to the closure frame and fix, stable in structure, the practicality is strong.

Preferably, a plurality of through holes are respectively arranged on the first reinforcing plate and the second reinforcing plate in a penetrating manner.

Through adopting above-mentioned technical scheme, the building adopts concrete placement's mode to realize the shaping usually when the shaping, wherein, buries buried the in-process in the building with pre-buried mounting underground, and first gusset plate and second gusset plate can be worn to establish from through-hole department to the concrete of fluid form, to the through-hole joint after the concrete solidification in the through-hole for stability when pre-buried mounting is installed obtains further promotion.

In summary, the present application includes at least one of the following beneficial technical effects:

1. in the process of installing the door and window body, the door and window body is only required to be covered to the locking frame, and the locking mechanism is started, so that the door and window body is locked, the door and window body is finally installed, the installation process is convenient and fast, and the installation efficiency of the door and window body is improved;

2. when the sliding clamping block moves to the clamping section, the tension spring applies elasticity to the sliding clamping block, the sliding clamping block is abutted with the wall of the locking groove in an attaching mode, the sliding clamping block fastens and fixes the door and window body at the moment, and the structure is stable;

3. the worm wheel and the worm have a self-locking function when being meshed with each other, so that the structure can be locked in a conventional state, and the overall stability of the structure is improved.

Drawings

Fig. 1 is a schematic structural diagram of the present application.

Fig. 2 is a schematic view of an assembly relationship between the door and window body and the locking frame according to the present application.

Fig. 3 is a partial cross-sectional view of the closure of the present application.

FIG. 4 is a schematic structural diagram of the transmission assembly and the power input assembly of the present application.

FIG. 5 is a schematic view of the present application showing the assembled relationship of the transmission assembly and the clamping assembly.

Fig. 6 is a schematic structural view between the clip assembly and the second frame of the present application.

Description of reference numerals: 1. locking the frame; 101. a first frame body; 1011. positioning a groove; 102. pre-burying a fixing piece; 1021. a first reinforcing plate; 1022. a second reinforcing plate; 1023. a through hole; 2. a locking mechanism; 21. a power input assembly; 211. a turbine; 212. a worm; 213. a hand wheel; 22. a transmission assembly; 221. a main transmission part; 2211. a first connecting shaft; 2212. a first bevel gear; 222. a sub-transmission section; 23. a clamping assembly; 231. a second connecting shaft; 2311. a limiting groove; 232. slipping the clamping block; 2321. a limiting boss; 233. a tension spring; 234. a limiting block; 3. a door and window body; 31. a second frame body; 32. a window sash; 33. a locking groove; 331. an inclined section; 332. a clamping section.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The embodiment of the application discloses a high-efficiency door and window installation method. The method comprises the following steps:

s1: the pre-assembling locking frame 1 is used for pre-assembling the locking mechanism 2 in the locking frame 1, starting the rotating hand wheel 213 and checking whether the sliding clamping block 232 rotates smoothly so as to test the operation fluency of the locking mechanism 2;

s2: installing the locking frame 1, and embedding the locking frame 1 into a window opening of a building. During the process of pouring and forming the wallboard, a pouring template is installed, the locking frame 1 is fixed at the position of the pouring template, then concrete is poured into the template, the concrete is filled around the embedded fixing piece 102, then the concrete is waited to be solidified, the embedded fixing piece 102 is embedded into a building, and the installation of the locking frame 1 is realized;

s3: installing the door and window body 3, hanging the door and window body 3 by a crane, then covering and positioning the door and window body 3 into the locking frame 1 along the vertical direction until the door and window body 3 is abutted and positioned with the positioning groove 1011, rotating the hand wheel 213, starting the locking mechanism 2 on the locking frame 1 at the moment, rotationally locking the sliding clamping block into the locking groove 33, and locking and fixing the periphery of the door and window body 3 by the locking mechanism 2 at the moment;

s4: the installation stability of the door and window body 3 is checked and accepted.

Referring to fig. 1, the installation method adopts the following installation structure, which includes a locking frame 1, a locking mechanism 2 and a door and window body 3, wherein the locking frame 1 is embedded into a window opening of a building, the locking mechanism 2 is installed in the locking frame 1, the door and window body 3 is covered and positioned in the locking frame 1, the locking mechanism 2 locks and fixes the door and window body 3 in the circumferential direction, and the locking frame 1 is used for supporting and installing the locking mechanism 2 and the door and window body 3.

Referring to fig. 1 and 2, the locking frame 1 includes a first frame body 101 and a plurality of embedded fixing members 102 disposed around the first frame body 101, in this embodiment, the first frame body 101 includes four frame rods connected end to end in sequence, the four frame rods form a rectangular frame-shaped first frame body 101, and two adjacent frame rods are welded and fixed.

In addition, the embedded fixing member 102 is fixedly installed on the four frame rods respectively, the embedded fixing member 102 includes a first reinforcing plate 1021 and a second reinforcing plate 1022, in this embodiment, the first reinforcing plate 1021 and the second reinforcing plate 1022 are both arranged in a shape of a strip, a side edge of one side of the first reinforcing plate 1021 is fixedly connected with the locking frame 1, generally, the first reinforcing plate 1021 and the locking frame 1 are fixed by welding, the first reinforcing plate 1021 is vertically arranged on the locking frame 1, and a length direction of the first reinforcing plate 1021 is consistent with a length direction of the frame rods; the middle portion of the second reinforcing plate 1022 is fixedly connected to the first reinforcing plate 1021 and the other side away from the frame bar, and generally, the second reinforcing plate 1022 may be fixedly connected to the first reinforcing plate 1021 by welding, the first reinforcing plate 1021 and the second reinforcing plate 1022 have the same length direction, and the first reinforcing plate 1021 and the second reinforcing plate 1022 are perpendicular to each other, so that the first reinforcing plate 1021 and the second reinforcing plate 1022 form a T-shaped arrangement. In addition, a plurality of through holes 1023 penetrate through the first reinforcing plate 1021 and the second reinforcing plate 1022 respectively, the specific number of the through holes 1023 can be ten, twenty, thirty or forty, and the like, and the specific number of the through holes 1023 is not limited herein, and the specific number of the through holes 1023 can be correspondingly arranged according to actual needs.

Here, pre-buried mounting 102 is used for inlaying and establishes to the building in, in the installation, the shaping need be realized through concrete placement's mode to the wall body of building, at this moment, support closure frame 1 through building the template bearing structure for pre-buried mounting 102 can be in the concrete mud of embedding of wall body pouring in-process, at this moment, concrete mud flows to first gusset plate 1021 and second gusset plate 1022 around, concrete mud passes through-hole 1023, wait for the concrete cooling, pre-buried mounting 102 can imbed to the building in, can realize carrying out the lock joint to closure frame 1 fixedly, closure frame 1 realizes fixed mounting.

Referring to fig. 2, the door/window body 3 generally includes a rectangular frame-shaped second frame body 31 and a window sash 32 rotatably mounted on the second frame body 31, the inner edge of the first frame body 101 may be recessed from outside to inside to form a positioning groove 1011, the length and width dimensions of the outer edge of the positioning groove 1011 are adapted to the length and width dimensions of the second frame body 31, the second frame body 31 may be placed in the positioning groove 1011, and the second frame body 31 may be abutted against the groove wall of the positioning groove 1011 for limitation, at this time, the door/window body 3 may be placed in the locking frame 1 for positioning.

Referring to fig. 3 and 4, the locking mechanism 2 is used for locking and fixing the door and window body 3 placed in the locking frame 1, a frame rod of the locking frame 1 is arranged in a hollow manner, the frame rod can be formed by welding a plurality of plates, and the locking mechanism 2 is accommodated in the frame rod of the locking frame 1.

Specifically, the locking mechanism 2 comprises a power input assembly 21, a transmission assembly 22 and a clamping assembly 23 which are connected in sequence, the clamping assembly 23, the transmission assembly 22 and the power input assembly 21 are all connected in the locking frame 1 in a rotating mode, the power input assembly 21 is used for inputting torque to the transmission assembly 22 in a mode used by workers, and the transmission assembly 22 is used for transmitting the torque to the clamping assembly 23, so that the clamping assembly 23 rotates towards the door and window body 3. Here, the plurality of clamping assemblies 23 are provided, and the plurality of clamping assemblies 23 are uniformly arranged along the circumferential direction of the locking frame 1, for example, the number of the clamping assemblies 23 may be four, eight, or sixteen, and in this embodiment, the number of the clamping assemblies 23 is four, and the four clamping assemblies 23 are respectively provided at four frame rods of the locking frame 1. In addition, a plurality of locking grooves 33 are arranged at the periphery of the door and window body 3, and fig. 2 can be combined here; the number of the locking grooves 33 is matched with the number of the clamping assemblies 23, that is, in this embodiment, the number of the locking grooves 33 is four, the four locking grooves 33 are respectively recessed from the outside to the inside and are disposed at the peripheral surfaces of the four sides of the second frame 31, and the clamping assemblies 23 can be rotated and fastened in the locking grooves 33 one by one, so as to lock and fix the door/window body 3.

With continued reference to fig. 3, in order to achieve torque input, the power input assembly 21 includes a worm wheel 211, a worm 212 and a hand wheel 213, the worm 212 is arranged along the horizontal direction, and the worm 212 is rotatably supported on the locking frame 1 through a bearing; one end of the worm 212 penetrates the exterior of the lock frame 1, the hand wheel 213 is fixedly installed at one end of the worm 212 extending outwards, the worm wheel 211 is fixedly connected to the transmission assembly 22, the worm wheel 211 is meshed with the worm 212, the hand wheel 213 can drive the worm 212 to rotate by rotating the hand wheel 213, the worm wheel 211 meshed with the worm 212 correspondingly rotates during rotation of the worm 212, the worm wheel 211 drives the transmission assembly 22 to rotate, and further torque input at the transmission assembly 22 is achieved.

Referring to fig. 4, the transmission assembly 22 is arranged around the periphery of the locking frame 1, and the transmission assembly 22 is connected to a plurality of clamping assemblies 23 in turn, that is, in this embodiment, the transmission assembly 22 is connected to four clamping assemblies 23 in turn. Specifically, the transmission assembly 22 includes a plurality of main transmission portions 221 and a plurality of sub transmission portions 222; in the present embodiment, there are four main transmission portions 221 and four sub-transmission portions 222, the four main transmission portions 221 are respectively and correspondingly rotatably connected to four frame rods of the locking frame 1, the four main transmission portions 221 are sequentially connected end to end, the main transmission portions 221 are circumferentially arranged along the circumferential direction of the locking frame 1, and the power input assembly 21 is connected to any one of the main transmission portions 221.

The main transmission part 221 includes a first connecting shaft 2211 and a first bevel gear 2212, the length direction of the first connecting shaft 2211 is consistent with the length direction of the frame rod, two bearing seats are fixedly mounted on the inner wall of the frame rod, two ends of the first connecting shaft 2211 are respectively rotatably supported on the two bearing seats, at this time, the first connecting shaft 2211 is rotatably connected with the locking frame 1, and further the main transmission part 221 is rotatably connected with the locking frame 1. The first bevel gears 2212 are respectively and fixedly installed at two ends of the first connecting shafts 2211, two first bevel gears 2212 on any two adjacent first connecting shafts 2211 are meshed with each other, the turbine 211 is fixedly installed on any one first connecting shaft 2211, at this time, the turbine 211 can drive the first connecting shaft 2211 to rotate, the first connecting shaft 2211 sequentially transmits torque to the rest first connecting shafts 2211 through the first bevel gears 2212, and therefore the four first connecting shafts 2211 rotate simultaneously.

In addition, the four sub-transmission portions 222 are respectively and correspondingly disposed on the four frame rods of the locking frame 1, at this time, the sub-transmission portions 222 are circumferentially arranged along the circumferential direction of the locking frame 1, and the four sub-transmission portions 222 are respectively connected to the four first connecting shafts 2211, so that the sub-transmission portions 222 are connected to the main transmission portion 221, and in addition, the four sub-transmission portions 222 are also respectively and correspondingly connected to the four clamping assemblies 23 at the same time, and the sub-transmission portions play a role in splitting the torque. Specifically, the sub-transmission portion 222 includes second bevel gears, the second bevel gears are respectively and fixedly mounted on the first connecting shaft 2211 and the clamping component 23, the two second bevel gears respectively fixed on the main transmission portion 221 and the clamping component 23 are mutually engaged, and the two second bevel gears mutually engaged can output the torque split to the clamping component 23, so that the clamping component 23 can realize the rotation buckling action.

Referring to fig. 5 and 6, the snap-fit assembly 23 and the locking groove 33 are engaged with each other. The clamping assembly 23 includes a second connecting shaft 231, a sliding clamping block 232, a tension spring 233 and a limiting block 234. The second connecting shaft 231 is arranged along the horizontal direction, a bearing seat can be fixedly installed in the frame rod, the second connecting shaft 231 is rotatably supported on the bearing seat, and at the moment, the second connecting shaft 231 is rotatably connected to the locking frame 1, so that the clamping assembly 23 is rotatably connected with the locking frame 1; the second bevel gear is fixedly installed on the second connecting shaft 231, at this time, the second connecting shaft 231 is connected to the transmission assembly 22, and when the first connecting shaft 2211 rotates, the second connecting shaft 231 rotates under the transmission action of the second bevel gear.

In addition, the sliding clamping block 232 is a waist-shaped block, one end of the sliding clamping block 232 is provided with a sleeving hole penetrating through two sides, a limiting boss 2321 is convexly arranged at the hole wall of the sleeving hole, a limiting groove 2311 is concavely arranged at the peripheral surface of the second connecting shaft 231 from outside to inside, the limiting groove 2311 extends along the length direction of the second connecting shaft 231, the sliding clamping block 232 is sleeved on the second connecting shaft 231 through the sleeving hole, the limiting boss 2321 is embedded into the limiting groove 2311, the surface of the limiting boss 2321 is in sliding and abutting contact with the groove wall of the limiting groove 2311, the sliding fit between the limiting groove 2311 and the limiting boss 2321 can guide the sliding clamping block 232 in a movement manner, so that the sliding clamping block 232 can be connected to the second connecting shaft 231 in a sliding manner along the length direction of the second connecting shaft 231, and further the sliding clamping block 232 can slide in a reciprocating manner in the length direction of the second connecting shaft 231.

In addition, the tension spring 233 is fixed to the sliding block 232 and the locking frame 1, respectively, in this embodiment, one end of the tension spring 233 is fixed to the bearing seat, and the tension spring 233 is fixed to the locking frame 1 through the bearing seat. A through hole is arranged on the locking frame 1 in a penetrating manner, two ends of the through hole are respectively opposite to the sliding clamping block 232 and the locking groove 33, at the moment, the sliding clamping block 232 can be opposite to the locking groove 33 through the through hole, and the second connecting shaft 231 drives the sliding clamping block 232 to rotate towards the locking groove 33 through the through hole when rotating; the groove wall of one side of the locking groove 33 is provided with an inclined section 331 and a clamping section 332, the width inside the locking groove 33 is gradually reduced from one side of the inclined section 331 to one side of the clamping section 332, the sliding clamping block 232 slides and abuts against the inclined section 331 and the clamping section 332 in sequence in the process of rotating and clamping to the locking groove 33, the inclined section 331 and the clamping section 332 push the sliding clamping block 232 to be far away from the bearing seat, at the moment, the sliding clamping block 232 slides on the second connecting shaft 231 and stretches the tension spring 233, when the sliding clamping block 232 moves to the clamping section 332, the tension spring 233 is arranged in a stretching shape, the sliding clamping block 232 abuts against the groove wall of the locking groove 33, the tension spring 233 exerts elasticity on the sliding clamping block 232, and the sliding clamping block 232 clamps and fixes the door and window body 3 in a buckling mode towards the inside direction of the positioning groove 1011 at the moment.

In addition, the limiting block 234 is fixedly connected to one end, far away from the bearing seat, of the second connecting shaft 231, the limiting block 234 abuts against the sliding clamping block 232 for limiting, when the sliding clamping block 232 moves to the clamping section 332, the limiting block 234 abuts against the sliding clamping block 232, and here, the sliding clamping block 232 is limited, so that the sliding clamping block 232 is not easy to loosen and fall off to the outside of the second connecting shaft 231 when sliding.

The implementation principle of the high-efficiency door and window installation method in the embodiment of the application is as follows: the door and window body 3 is covered in the locking frame 1, the hand wheel 213 is rotated, the hand wheel 213 drives the worm 212 to rotate, the worm 212 drives the worm wheel 211 to rotate, the worm wheel 211 drives the first connecting shaft 2211 to rotate, the first connecting shaft 2211 drives the second connecting shaft 231 to rotate, the second connecting shaft 231 drives the sliding clamping block 232 to rotate and be buckled in the locking groove 33, at the moment, the door and window body 3 is locked and fixed, the process is convenient and fast, and the installation efficiency is high.

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

Claims (10)

1. A high-efficiency door and window installation method is characterized in that: the method comprises the following steps:

s1: the pre-assembling locking frame (1) is used for pre-assembling the locking mechanism (2) in the locking frame (1), and starting the locking mechanism (2) so as to test the operation fluency of the locking mechanism (2);

s2: installing a locking frame (1), and embedding the locking frame (1) into a window opening of a building;

s3: installing a door and window body (3), covering and positioning the door and window body (3) into the locking frame (1) along the vertical direction, starting the locking mechanism (2) on the locking frame (1), and locking and fixing the periphery of the door and window body (3) by the locking mechanism (2);

s4: the installation stability of the door and window body (3) is checked and accepted.

2. The method for installing the efficient door and window as claimed in claim 1, wherein the method for installing the efficient door and window adopts the following installation structure, and is characterized in that: comprises a locking frame (1), a locking mechanism (2) and a door and window body (3);

the locking frame (1) comprises a first frame body (101) and a plurality of embedded fixing pieces (102) arranged along the periphery of the first frame body (101), and the embedded fixing pieces (102) are embedded into a building;

the locking mechanism (2) comprises a power input assembly (21), a transmission assembly (22) and a clamping assembly (23);

the clamping assembly (23) is rotatably connected to the locking frame (1), the clamping assemblies (23) are multiple, the clamping assemblies (23) are uniformly arranged along the peripheral direction of the locking frame (1), the door and window body (3) is covered and positioned in the locking frame (1), a plurality of locking grooves (33) are formed in the peripheral edge of the door and window body (3), and the clamping assemblies (23) are rotatably buckled in the locking grooves (33);

the transmission assembly (22) is rotatably connected to the locking frame (1), the transmission assembly (22) is arranged around the periphery of the locking frame (1), the transmission assembly (22) is sequentially connected with the clamping assemblies (23), and the transmission assembly (22) is used for transmitting torque to the clamping assemblies (23) so as to enable the clamping assemblies (23) to rotate;

the power input assembly (21) is rotationally connected into the locking frame (1), the power input assembly (21) is connected with the transmission assembly (22), and the power input assembly (21) is used for inputting torque to the transmission assembly (22) so that the transmission assembly (22) drives the clamping assembly (23) to rotate.

3. The method for mounting a high-efficiency door window according to claim 2, wherein: the power input assembly (21) comprises a worm wheel (211), a worm (212) and a hand wheel (213), the worm (212) is rotatably connected into the locking frame (1), the worm wheel (211) is fixedly connected onto the transmission assembly (22), the hand wheel (213) is fixedly connected onto the worm (212), and the worm wheel (211) is meshed with the worm (212).

4. The method for mounting a high-efficiency door window according to claim 2, wherein: the transmission assembly (22) comprises a plurality of main transmission parts (221) and a plurality of sub transmission parts (222);

the main transmission parts (221) are rotatably connected to the locking frame (1), a plurality of main transmission parts (221) are arranged in a surrounding mode along the circumferential direction of the locking frame (1), a plurality of main transmission parts (221) are sequentially connected end to end, and the power input assembly (21) is connected with any one main transmission part (221);

the plurality of sub-transmission parts (222) are arranged in a surrounding mode along the circumferential direction of the locking frame (1), and the sub-transmission parts (222) are connected with the main transmission part (221) and the clamping assembly (23) respectively.

5. The method for mounting a high-efficiency door or window according to claim 4, wherein: the main transmission part (221) comprises a first connecting shaft (2211) and first bevel gears (2212), the first bevel gears (2212) are respectively and fixedly connected to two ends of the first connecting shaft (2211), two first bevel gears (2212) on any two adjacent first connecting shafts (2211) are meshed with each other, and the first connecting shaft (2211) is respectively connected with the sub transmission part (222) and the power input assembly (21).

6. The method for mounting a high-efficiency door or window according to claim 4, wherein: the sub-transmission part (222) comprises second bevel gears, and the second bevel gears are fixedly connected to the main transmission part (221) and the clamping component (23) respectively and are fixedly connected to the main transmission part (221) and two second bevel gears on the clamping component (23) to be meshed with each other.

7. The method for mounting a high-efficiency door window according to claim 2, wherein: the clamping assembly (23) comprises a second connecting shaft (231), a sliding clamping block (232) and a tension spring (233);

the second connecting shaft (231) is rotatably connected to the locking frame (1), and the second connecting shaft (231) is connected with the transmission assembly (22);

the sliding clamping block (232) is connected to the second connecting shaft (231) in a sliding mode along the length direction of the second connecting shaft (231);

the tension spring (233) is respectively fixed with the sliding clamping block (232) and the locking frame (1);

slip clamp splice (232) with it is relative to lock groove (33), second connecting axle (231) are used for the drive slip clamp splice (232) rotate the lock extremely in lock groove (33), one side cell wall of lock groove (33) has slope section (331) and joint section (332), slip clamp splice (232) rotate the lock extremely in-process in lock groove (33), slip clamp splice (232) in proper order with slope section (331) and joint section (332) butt that slides, work as slip clamp splice (232) with during joint section (332) butt, extension spring (233) are tensile form setting.

8. The method for mounting a high-efficiency door or window according to claim 7, wherein: the clamping assembly (23) further comprises a limiting block (234), the limiting block (234) is fixedly connected to the second connecting shaft (231), and the limiting block (234) is abutted and limited to the sliding clamping block (232).

9. The method for mounting a high-efficiency door or window according to claim 1, wherein: the embedded fixing piece (102) comprises a first reinforcing plate (1021) and a second reinforcing plate (1022), wherein the side edge of one side of the first reinforcing plate (1021) is fixedly connected with the locking frame (1), the second reinforcing plate (1022) is fixedly connected to the other side of the first reinforcing plate (1021), and the first reinforcing plate (1021) and the second reinforcing plate (1022) are perpendicular to each other.

10. The method for mounting a high-efficiency door or window according to claim 9, wherein: the first reinforcing plate (1021) and the second reinforcing plate (1022) are respectively provided with a plurality of through holes (1023) in a penetrating manner.

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