CN220336204U - Novel curtain wall node - Google Patents

Abstract

The utility model relates to a novel curtain wall node which comprises a first curtain wall unit, an installation unit, a splicing unit and a second curtain wall unit, wherein the first curtain wall unit is vertically arranged; the first end of the mounting unit is connected with the first curtain wall unit; the first end of the splicing unit is connected with the second end of the mounting unit; the device is used for assembling curtain walls; the second curtain wall unit is connected with the second end of the splicing unit. The first curtain wall unit can be stably fixed at the corresponding wall body through the mounting unit, so that the stability is met when the curtain wall is spliced later; the second curtain wall unit is spliced by the splicing unit, so that the assembly stability is improved, and the installation is convenient.

Description

Novel curtain wall node

Technical Field

The utility model relates to the technical field related to building structures, in particular to a novel curtain wall node.

Background

With the continuous improvement of the construction level, the outer vertical surfaces are increased, and the following problems are the increase of the processing cost and the difficulty of curtain wall construction parts. Curtain wall, by panel and supporting structure system constitution, can have certain displacement ability or self have certain deformability to the major structure, do not bear the building peripheral protection structure or the decorative structure that the major structure acted on, common curtain wall structural style: conventional straight-face curtain walls, single-curved curtain walls and double-curved curtain walls.

When installing the curtain, two adjacent curtain are generally installed through bolt and nut cooperation for when beginning the assembly correction, the operation is comparatively loaded down with trivial details like this, thereby leads to the installation degree of difficulty increase, and the installation progress is easily influenced, produces adverse effect to installation effectiveness and installation effect.

At present, no effective solution is proposed for solving the problems of complicated curtain wall assembly operation and adverse effect on installation effect in the related art.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art, and provides a novel curtain wall node to solve the problems that the curtain wall assembly operation is complicated and the installation effect is adversely affected in the related art.

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

a novel curtain wall node comprising:

the first curtain wall unit is vertically arranged;

the first end of the installation unit is connected with the first curtain wall unit;

the first end of the splicing unit is connected with the second end of the mounting unit;

and the first end of the second curtain wall unit is connected with the second end of the splicing unit.

In some of these embodiments, the first curtain wall unit comprises:

a first fa sigmaade element arranged vertically;

the first positioning element horizontally penetrates through the first curtain wall element and is connected with the mounting unit.

In some of these embodiments, the mounting unit comprises:

a first mounting element connected to the first curtain wall unit;

the second positioning element is arranged on one side of the first mounting element and is detachably connected with the first curtain wall unit;

the second installation element is arranged at the rear side of the first curtain wall unit and is detachably connected with the second positioning element and the first curtain wall unit respectively;

and the first fixing element is respectively connected with the second installation element and the wall body and is used for fixing the first curtain wall unit on the wall body.

In some of these embodiments, the mounting unit further comprises:

a first connecting element, which is arranged through the first mounting element and the second positioning element;

a second connecting element provided at one side of the second mounting element;

the second fixing element is respectively connected with the first connecting element and the second connecting element.

In some of these embodiments, the splice unit comprises:

a base member, a bottom end of which is connected with the mounting unit;

a first splice member disposed on top of the base member and connected to the first end of the second curtain wall unit;

a chamber element disposed inside the base element and in communication with the first splice element;

the first movable element is arranged in the cavity element in a sliding manner along the horizontal direction and is abutted with the first end of the second curtain wall unit;

the second movable element is slidably arranged in the chamber element along the vertical direction and is abutted with the first movable element, and the second movable element is used for driving the first movable element to reciprocate along the horizontal direction.

In some of these embodiments, the splice unit further comprises:

a first sliding element disposed inside the chamber element;

a second sliding element connected to the second movable element and slidingly connected to the first sliding element for defining a direction of movement of the second movable element;

in some of these embodiments, the splice unit further comprises:

the driving element is connected with the second movable element and is used for driving the second movable element to reciprocate along the vertical direction;

in some of these embodiments, the splice unit further comprises:

a third sliding element disposed inside the chamber element;

and the fourth sliding element is connected with the first movable element and is in sliding connection with the third sliding element and is used for limiting the movement direction of the first movable element.

In some of these embodiments, the splice unit further comprises:

and the elastic element is respectively connected with the third sliding element and the fourth sliding element.

In some of these embodiments, the splice unit further comprises:

the first locking element is arranged on one side of the first movable element and is in locking connection with the first end of the second curtain wall unit.

In some of these embodiments, the second curtain wall unit comprises:

a second fa sigmaade element arranged on top of the splice unit;

and the second splicing element is arranged at the first end of the second curtain wall element and is connected with the splicing unit.

In some of these embodiments, the second curtain wall unit further comprises:

and the second locking element is arranged on one side of the second splicing element and is connected with the splicing unit for fixing the second curtain wall element to the splicing unit.

Compared with the prior art, the utility model has the following technical effects:

according to the novel curtain wall node, the first curtain wall unit can be stably fixed at the corresponding wall body through the mounting unit, so that the stability is met when the curtain wall is spliced later; and the second curtain wall unit is spliced through the splicing unit, the splicing unit and the second curtain wall unit are firstly aligned and clamped so as to increase the assembly stability, and then the second curtain wall unit is assembled and fixed so as to be convenient to install.

Drawings

FIG. 1 is a schematic perspective view of a novel curtain wall node according to an embodiment of the present utility model;

FIG. 2 is a schematic perspective view of a first curtain wall unit according to an embodiment of the present utility model;

fig. 3 is a schematic structural view of a mounting unit according to an embodiment of the present utility model;

fig. 4 is a schematic perspective view of an inner portion of a splice unit according to an embodiment of the present utility model;

FIG. 5 is an enlarged view of a portion of FIG. 4 at B in accordance with an embodiment of the present utility model;

FIG. 6 is a schematic perspective view of an interior portion of a base member according to an embodiment of the present utility model;

FIG. 7 is a side cross-sectional view of a splice unit according to an embodiment of the utility model;

FIG. 8 is a top cross-sectional view of a splice unit according to an embodiment of the utility model;

FIG. 9 is a schematic perspective view of a second curtain wall unit according to an embodiment of the present utility model;

wherein the reference numerals are as follows: 100. a first curtain wall unit; 101. a first fa sigmaade element; 102. a first positioning element;

200. an installation unit; 201. a first mounting element; 202. a second positioning element; 203. a second mounting element; 204. a first fixing element; 205. a first connecting element; 206. a second connecting element; 207. a second fixing element;

300. a splicing unit; 301. a base member; 302. a first splice member; 303. a chamber element; 304. a first movable element; 305. a second movable element; 306. a first sliding element; 307. a second sliding element; 308. a driving element; 309. a third sliding element; 310. a fourth sliding element; 311. an elastic element; 312. a first locking element;

400. a second curtain wall unit; 401. a second fa sigmaade element; 402. a second splice element; 403. a second locking element.

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.

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other.

The utility model is further described below with reference to the drawings and specific examples, which are not intended to be limiting.

An exemplary embodiment of the present utility model, as shown in fig. 1, a novel curtain wall node includes a first curtain wall unit 100, an installation unit 200, a splice unit 300, and a second curtain wall unit 400. Wherein the first curtain wall unit 100 is vertically disposed; the first end of the installation unit 200 is connected with the first curtain wall unit 100; the first end of the splice unit 300 is connected to the second end of the mounting unit 200; the first end of the second curtain wall unit 400 is connected to the second end of the splice unit 300.

Specifically, the first curtain wall unit 100 is fixed to the wall body by the installation unit 200; the second curtain wall unit 400 is spliced and installed with the first curtain wall unit 100 through the splicing unit 300, and the splicing unit 300 is firstly connected with the second curtain wall unit 400 in a clamping manner in a counterpoint mode to improve assembly stability, and is fixed through bolt matching subsequently so as to be convenient to install.

As shown in fig. 2, the first fa sigmaade element 100 comprises a first fa sigmaade element 101 and a first positioning element 102. Wherein the first fa sigmaade element 101 is arranged vertically; the first positioning element 102 is arranged horizontally through the first fa sigmaade element 101 and is connected to the mounting unit 200.

The cross section of the first fa sigmaade element 101 has a rectangular configuration.

In some of these embodiments, the first fa sigmaade element 101 is a tempered glass curtain wall.

The first positioning element 102 has a convex cross-section. Specifically, the first positioning element 102 includes a first card slot and a second card slot. Wherein the first clamping groove is arranged on the front end surface of the first curtain wall element 101; the second clamping groove is arranged on the rear end surface of the first fa sigmaade element 101 and communicates with the first clamping groove.

The size of the first clamping groove is matched with that of the second clamping groove. Generally, the length of the first clamping groove is equal to that of the second clamping groove, and the height and the width of the first clamping groove are larger than those of the second clamping groove.

The first positioning elements 102 are several. A number of first positioning elements 102 are arranged in an array on the end face of the first fa sigmaade element 101.

Wherein the first positioning elements 102 are arranged in a row x b column. Wherein a is greater than or equal to 1, and b is greater than or equal to 2. I.e. at least one first positioning element 102 is arranged on both the left and right sides of the first fa sigmaade element 101.

In some of these embodiments, a=2 and b=2. That is, a first positioning element 102 is provided at each of the four corner positions of the first fa sigmaade element 101.

In some embodiments, the first positioning element 102 is a clamping groove.

As shown in fig. 3, the mounting unit 200 includes a first mounting member 201, a second positioning member 202, a second mounting member 203, and a first fixing member 204. Wherein the first mounting element 201 is connected to the first curtain wall unit 100; the second positioning element 202 is disposed at one side of the first mounting element 201 and is detachably connected with the first curtain wall unit 100; the second installation element 203 is arranged at the rear side of the first curtain wall unit 100 and is detachably connected with the second positioning element 202 and the first curtain wall unit 100 respectively; the first fixing member 204 is connected to the second mounting member 203 and the wall body, respectively, for fixing the first curtain wall unit 100 to the wall body.

In particular, the first mounting element 201 is connected to the first fa sigmaade element 101; the second positioning element 202 is detachably connected with the first positioning element 102; the second mounting element 203 is arranged on the rear side of the first fa sigmaade element 101 and is detachably connected to the second positioning element 202, the first fa sigmaade element 101, respectively.

The first mounting element 201 has an L-shaped cross-section. Specifically, the first mounting element 201 includes a cross plate and a riser. Wherein the cross plate is connected to the top or bottom end surface of the first fa sigmaade element 101; the risers are arranged perpendicular to the cross plates and are connected to the front end face of the first fa sigmaade element 101.

The first mounting elements 201 are several. In the case of several first installation elements 201, several first installation elements 201 are arranged symmetrically up and down on the end face of the first fa sigmaade element 101.

Typically, a first mounting element 201 is arranged above the end face of the first fa sigmaade element 101, and a first mounting element 201 is arranged below the end face of the first fa sigmaade element 101.

In some of these embodiments, the first mounting member 201 is made of a metal material.

In some of these embodiments, the first mounting element 201 is a mounting bracket.

The second positioning element 202 is arranged on the inside of the riser of the first mounting element 201, i.e. towards the side of the first fa sigmaade element 101. The second positioning element 202 has a rectangular column structure.

The number of the second positioning elements 202 is several. In the case that the number of the second positioning elements 202 is several, the second positioning elements 202 are symmetrically disposed at one side of the first mounting element 201.

Generally, a second positioning element 202 is disposed at the left end of the first mounting element 201, and a second positioning element 202 is disposed at the right end of the first mounting element 201.

The dimensions of the second positioning element 202 match the dimensions of the first positioning element 102. In general, the length, width, and height of the second positioning element 202 are equal to the length, width, and height of the first positioning element 102.

In some of these embodiments, the second positioning element 202 is fixedly coupled to the first mounting element 201, including but not limited to welding.

In some embodiments, the second positioning element 202 is made of metal.

In some embodiments, the second positioning element 202 is a latch.

The second mounting element 203 has a T-shaped cross-section. Specifically, the second mounting member 203 includes a first fixing plate, a second fixing plate, and a through hole. Wherein the first fixing plate is connected with the second clamping groove of the first positioning element 102; the second fixing plate is fixedly connected with the first fixing plate; the through hole is arranged on the end face of the second fixing plate and penetrates through the second fixing plate.

The size of the second fixing plate is matched with that of the first fixing plate. Generally, the height of the second fixing plate is greater than the height of the first fixing plate, the length of the second fixing plate is equal to the length of the first fixing plate, and the width of the second fixing plate is smaller than the width of the first fixing plate.

In some of these embodiments, the through holes are several. The plurality of through holes are uniformly distributed at four corners of the second mounting member 203.

Typically, the number of through holes is four. Four through holes are uniformly provided at four corners of the second mounting member 203.

The number of second mounting elements 203 matches the number of second positioning elements 202. Generally, the number of second mounting elements 203 is equal to the number of second positioning elements 202.

In some of these embodiments, the second mounting element 203 is made of a metallic material.

In some of these embodiments, the second mounting element 203 is a support bracket.

The first fixing element 204 has a cylindrical structure.

The number of first fixing elements 204 matches the number of second mounting elements 203. Typically, the number of first fixation elements 204 is an integer multiple of the number of second mounting elements 203. I.e. each second mounting element 203 is provided with at least one first fixing element 204.

Specifically, the number of first fixing elements 204 is equal to the number of through holes.

In some of these embodiments, the number of first fixation elements 204 is 2 times the number of second mounting elements 203. That is, each second mounting element 203 is correspondingly provided with two first fixing elements 204, in addition, one end of the second mounting element 203 is provided with a first fixing element 204, and the other end of the second mounting element 203 is provided with a first fixing element 204.

In some of these embodiments, the number of first fixation elements 204 is 4 times the number of second mounting elements 203. That is, each of the second mounting members 203 is provided with a first fixing member 204 at the corresponding four corners, and two first fixing members 204 are provided at one end of the second mounting member 203, and two first fixing members 204 are provided at the other end of the second mounting member 203.

In some of these embodiments, the first fixation element 204 is an expansion bolt.

Further, the mounting unit 200 further comprises a first connection element 205, a second connection element 206 and a second fixation element 207. Wherein the first connecting element 205 is disposed through the first mounting element 201 and the second positioning element 202; the second connecting element 206 is disposed on one side of the second mounting element 203; the second fixing member 207 is connected to the first connecting member 205 and the second connecting member 206, respectively.

The first connecting element 205 has a circular cross section.

The number of first connecting elements 205 matches the number of second positioning elements 202. Generally, the number of first connecting elements 205 is equal to the number of second positioning elements 202.

The first connecting element 205 is sized to match the riser size of the first mounting element 201. Generally, the radial dimension of the first connecting element 205 is smaller than the height/width of the riser of the first mounting element 201.

In some of these embodiments, the first connecting element 205 is a mounting hole.

The second connecting element 206 has a circular cross-section.

The number of second connection elements 206 matches the number of second mounting elements 203. Generally, the number of second connection elements 206 is equal to the number of second mounting elements 203.

The dimensions of the second connecting element 206 match the dimensions of the first fixing plate of the second mounting element 203. Generally, the radial dimension of the second connecting element 206 is smaller than the height/width of the first fixing plate of the second mounting element 203, and the depth of the second connecting element 206 is not larger than the first fixing plate length of the second mounting element 203.

In some of these embodiments, the second connecting element 206 is a first threaded bore.

The second fixing member 207 has a cylindrical structure.

The number of second fixing elements 207 matches the number of first connecting elements 205. Generally, the number of second fixation elements 207 is equal to the number of first connection elements 205.

In some of these embodiments, the second fixing element 207 is made of a metal material.

In some of these embodiments, the second fixation element 207 is a bolt.

As illustrated in fig. 4-8, the splice unit 300 includes a base element 301, a first splice element 302, a chamber element 303, a first movable element 304, and a second movable element 305. Wherein the bottom end of the base member 301 is connected to the mounting unit 200; the first splicing element 302 is disposed at the top end of the base element 301 and is connected to the first end of the second curtain wall unit 400; the chamber element 303 is disposed inside the base element 301 and is in communication with the first splice element 302; the first movable element 304 is slidably disposed in the cavity element 303 along the horizontal direction and abuts against the first end of the second curtain wall unit 400; the second movable element 305 is slidably disposed inside the chamber element 303 along the vertical direction, and abuts against the first movable element 304, so as to drive the first movable element 304 to reciprocate along the horizontal direction.

Specifically, the bottom end of the base member 301 is fixedly coupled to the first mounting member 201.

The base element 301 is a rectangular column.

In some of these embodiments, the base member 301 is fixedly coupled to the first mounting member 201, including but not limited to welding.

In some of these embodiments, the base member 301 is made of a metal material.

In some of these embodiments, the base element 301 is a fixed plate.

The first splice member 302 has a rectangular configuration in cross section.

The first splice member 302 is sized to match the size of the base member 301. Generally, the length, width, and height of the first splice member 302 are less than the length, width, and height of the base member 301.

In some of these embodiments, the first splice member 302 is a splice groove.

The cross-section of the chamber element 303 is of convex configuration. Specifically, the chamber element 303 comprises a first recess, a second recess and three second threaded holes. Wherein the first groove is disposed inside the base element 301; the second groove is disposed on a side portion of the first splicing element 302 and is in communication with the first groove, and the second threaded hole is disposed on an inner side of the first groove and penetrates through the first groove.

Typically, the three second threaded holes are evenly distributed inside the first recess.

The dimensions of the first recess match the dimensions of the second recess. Typically, the length, width and height of the first groove are all greater than the length, width and height of the second groove.

The dimensions of the chamber element 303 match those of the base element 301. Generally, the length, width and height of the chamber element 303 are all less than the length, width and height of the base element 301.

In some of these embodiments, the chamber element 303 is a mounting slot.

The first movable element 304 has a right trapezoid-shaped cross section. In particular, the bevel of the first movable element 304 faces the chamber element 303.

The dimensions of the first movable element 304 match the dimensions of the chamber element 303. Generally, the length, width and height of the first movable element 304 are all less than the length, width and height of the chamber element 303.

In some embodiments, the first movable element 304 is made of a metal material.

In some of these embodiments, the first movable element 304 is a first movable plate.

The second movable element 305 has a right trapezoid-shaped cross section. Specifically, the inclined surface of the second movable element 305 faces the first movable element 304, and the inclined surface of the second movable element 305 is wedge-shaped and engaged with the inclined surface of the first movable element 304. Specifically, as the second movable element 305 moves downward, the second movable element 305 presses the first movable element 304 toward the first splice element 302; when the second movable member 305 moves upward, the first movable member 304 moves toward the chamber member 303.

The dimensions of the second movable element 305 match the dimensions of the chamber element 303. Generally, the length, width and height of the second movable element 305 are all less than the length, width and height of the chamber element 303.

In some of these embodiments, the second movable element 305 is made of a metal material.

In some of these embodiments, the second movable element 305 is a second movable plate.

Further, the splice unit 300 further comprises a first sliding element 306 and a second sliding element 307. Wherein the first sliding element 306 is arranged inside the chamber element 303; the second sliding element 307 is connected to the second movable element 305 and is slidingly connected to the first sliding element 306 for defining the direction of movement of the second movable element 305.

The bottom end of the first sliding member 306 is fixedly connected to the chamber member 303.

The first sliding element 306 has a rectangular configuration. Specifically, the first sliding element 306 includes a fixed plate and a chute. Wherein the fixed plate is fixedly connected with the chamber element 303; the chute is arranged on the end face of the fixed plate.

The section of the chute is in a convex structure. Specifically, the chute includes a first chute and a second chute. The first chute is arranged in the fixing plate; the second chute is arranged on the end face of the fixed plate and is communicated with the first chute.

The size of the first chute is matched with that of the second chute. Generally, the height of the first chute is equal to the height of the second chute, and the length and width of the first chute are greater than those of the second chute.

The first sliding elements 306 are several. In the case that the number of the first sliding elements 306 is several, the several first sliding elements 306 are symmetrically disposed on the end surface of the cavity element 303.

Typically, a first sliding element 306 is provided on the left side of the end face of the chamber element 303, and a first sliding element 306 is provided on the right side of the end face of the chamber element 303.

The first slide member 306 is sized to match the first recess size of the chamber member 303. Generally, the height of the first sliding element 306 is equal to the height of the first groove of the chamber element 303, and the length and width of the first sliding element 306 are smaller than the length and width of the first groove of the chamber element 303.

In some of these embodiments, the first slide member 306 is fixedly coupled to the chamber member 303, including but not limited to welding.

In some of these embodiments, the first sliding element 306 is made of a metal material.

In some of these embodiments, the first sliding element 306 is a sliding rail.

The second sliding element 307 has a convex configuration in cross section. Specifically, the second sliding element 307 includes a first slider and a second slider. The first sliding block is in sliding connection with the first sliding groove; the second sliding block is arranged on one side of the first sliding block and is in sliding connection with the second sliding groove.

The dimensions of the first slider are matched with those of the second slider. Typically, the height of the first slider is equal to the height of the second slider, the length of the first slider is less than the length of the second slider, and the width of the first slider is greater than the width of the second slider.

The number of second sliding elements 307 matches the number of first sliding elements 306. Generally, the number of second sliding elements 307 is equal to the number of first sliding elements 306.

The dimensions of the second sliding element 307 match those of the first sliding element 306. Typically, the height of the second sliding element 307 is less than the height of the first sliding element 306.

In some of these embodiments, the second sliding element 307 is fixedly connected to the second movable element 305, including but not limited to welding.

In some of these embodiments, the second sliding element 307 is made of a metal material.

In some of these embodiments, the second sliding element 307 is a slide shoe.

Further, the splice unit 300 further comprises a drive element 308. Wherein, the driving element 308 is connected with the second movable element 305, and is used for driving the second movable element 305 to reciprocate along the vertical direction.

Specifically, the drive element 308 is threadedly coupled with the second threaded bore of the chamber element 303.

The driving element 308 has a cylindrical structure.

Specifically, the number of drive elements 308 is equal to the number of second threaded holes.

In some of these embodiments, the drive element 308 is a number. A plurality of driving elements 308 are disposed at the top end of the base element 301 at intervals along the horizontal direction.

In some of these embodiments, the drive elements 308 are three. Three driving elements 308 are uniformly disposed at the top end of the base element 301.

In some of these embodiments, the drive element 308 is not in separate rotational connection with the second movable element 305. For example, the driving element 308 is connected to the second movable element 305 via a bearing housing, and the contact surfaces are connected in a T-shaped configuration.

The bearing pedestal comprises a base and a bearing. Specifically, the base is fixedly connected to the second movable member 305, and the bearing is fixedly connected to the driving member 308 and rotatably connected to the base.

In some of these embodiments, the driving element 308 is made of a metal material.

In some of these embodiments, the drive element 308 is a bolt.

Further, the splice unit 300 further comprises a third 309 and a fourth 310 sliding element. Wherein the third sliding element 309 is arranged inside the chamber element 303; the fourth sliding element 310 is connected to the first movable element 304 and is slidingly connected to the third sliding element 309 for defining the direction of movement of the first movable element 304.

The third sliding member 309 has a rectangular structure in cross section.

The third sliding elements 309 are several. In the case that the number of the third sliding elements 309 is several, the third sliding elements 309 are symmetrically disposed on the left and right sides of the chamber element 303.

Typically, a third slide member 309 is provided on the left side of the chamber member 303 and a third slide member 309 is provided on the right side of the chamber member 303.

The dimensions of the third sliding element 309 match the dimensions of the first recess of the chamber element 303. Typically, the length of the third sliding element 309 is equal to the width of the first recess of the chamber element 303, and the height and width of the third sliding element 309 are smaller than the height and length of the first recess of the chamber element 303.

In some of these embodiments, the third sliding element 309 is a limiting chute.

The fourth sliding member 310 has an L-shaped cross section. Specifically, the fourth slide member 310 includes a first slide plate and a second slide plate. Wherein the first slide plate is in sliding connection with the third slide element 309; the second slide is disposed perpendicular to the first slide and is connected to the first slide and the first movable member 304, respectively.

The number of fourth sliding elements 310 matches the number of third sliding elements 309. Generally, the number of fourth slide elements 310 is equal to the number of third slide elements 309.

The size of the fourth sliding element 310 matches the size of the third sliding element 309. Generally, the height of the fourth slide element 310 is equal to the height of the third slide element 309.

In some of these embodiments, the fourth slide element 310 is fixedly coupled to the first movable element 304, including but not limited to welding.

In some embodiments, the fourth sliding element 310 is made of metal.

In some of these embodiments, the fourth slide element 310 is a slider.

Further, the splicing unit 300 further includes an elastic element 311. The elastic element 311 is connected to the third sliding element 309 and the fourth sliding element 310, respectively.

Specifically, the elastic elements 311 are fixedly connected to the third sliding element 309 at first ends thereof, and fixedly connected to the fourth sliding element 310 at second ends thereof.

The number of elastic elements 311 matches the number of fourth sliding elements 310. Generally, the number of elastic elements 311 is equal to the number of fourth sliding elements 310.

In some of these embodiments, the resilient member 311 is made of high carbon steel.

In some of these embodiments, the resilient element 311 is a spring.

Further, the splice unit 300 also includes a first locking element 312. The first locking element 312 is disposed on one side of the first movable element 304 and is locked to the first end of the second curtain wall unit 400.

The first locking element 312 is in a rack configuration. In particular, the racks are distributed in the vertical direction.

The first locking element 312 is sized to match the size of the first movable element 304. Generally, the length and height of the first locking element 312 is equal to the length and height of the first movable element 304.

In some of these embodiments, the first locking element 312 is a first rack.

As shown in fig. 9, the second curtain wall unit 400 comprises a second curtain wall element 401 and a second splice element 402. Wherein the second fa sigmaade element 401 is arranged in the upper part of the splice unit 300; the second splice member 402 is disposed at a first end of the second fa sigmaade element 401 and is connected to the splice unit 300.

In particular, the second fa sigmaade element 401 is arranged in the upper part of the base element 301; the second splice member 402 is connected to the first splice member 302.

The cross section of the second fa sigmaade element 401 has a rectangular configuration.

The dimensions of the second fa sigmaade element 401 match those of the first fa sigmaade element 101. In general, the length, width and height of the second fa sigmaade element 401 is equal to the length, width and height of the first fa sigmaade element 101.

In some of these embodiments, the second fa sigmaade element 401 is a tempered glass curtain wall.

The second splice member 402 has a rectangular configuration in cross section.

The dimensions of the second splice-element 402 are matched to the dimensions of the second fa sigmaade element 401. Typically, the length, width and height of the second splice-element 402 are all less than the length, width and height of the second fa sigmaade element 401.

The dimensions of the second splice member 402 match the dimensions of the first splice member 302. In general, the length, width, and height of the second splice member 402 are equal to the length, width, and height of the first splice member 302.

In some of these embodiments, the second splice-element 402 is fixedly attached to the second fa sigmaade element 401, including but not limited to welding.

In some of these embodiments, the second splice member 402 is made of a metallic material.

In some of these embodiments, the second splice element 402 is a splice block.

Further, the second curtain wall unit 400 also comprises a second locking element 403. Wherein the second locking element 403 is arranged at one side of the second splice element 402 and is connected to the splice unit 300 for securing the second fa sigmaade element 401 to the splice unit 300.

Specifically, the second locking element 403 is snapped into engagement with the first locking element 312.

The second locking element 403 is in a rack configuration. In particular, the racks are distributed in the vertical direction.

The dimensions of the second locking element 403 match the dimensions of the second splice element 402. Generally, the length and height of the second locking element 403 is equal to the length and height of the second splice element 402.

In some of these embodiments, the second locking element 403 is a second rack.

The application method of the utility model is as follows:

first mounting a first curtain wall unit

Firstly, a plurality of reserved holes are formed in a required wall, and the distances of the reserved holes correspond to the mounting positions of the second mounting elements 203;

secondly, correspondingly fixing the second mounting element 203 provided with the first fixing element 204 (namely expansion bolts) in a plurality of reserved holes so as to fix the second mounting element with the wall body;

thirdly, the first fa sigmaade element 101 is clamped in the second installation element 203 by the first positioning element 102 to complete the preliminary installation operation;

finally, the first installation element 201 is clamped into the first positioning element 102 by means of the second positioning element 202, and the second fixing element 207 is screwed by means of the first connecting element 205 through the first installation element 201 and the second connecting element 206 provided by the second positioning element 202 and the second installation element 203 until the first curtain wall element 101 is completely installed and fixed after being screwed tightly.

Second spliced second curtain wall unit

First, the second curtain wall element 401 is aligned and clamped into the first splicing element 302 by the second splicing element 402, so that the second locking element 403 is arranged at the opposite position to the first locking element 312;

then, the operator twists the driving element 308 to rotate in the base element 301, so as to drive the second movable element 305 to vertically move downwards along the first sliding element 306 through the second sliding element 307, and during the moving process, squeeze the first movable element 304, so as to drive the first movable element 304 to gradually move along the third sliding element 309 along the side close to the first splicing element 302 through the fourth sliding element 310, until the first locking element 312 is driven to be in fit and clamping connection with the second locking element 403, thereby completing the splicing installation of the second curtain wall element 401.

The utility model has the advantages that the first curtain wall unit can be stably fixed at the corresponding wall body through the mounting unit so as to meet the requirement of providing stability when the curtain wall is spliced later; and the second curtain wall unit is spliced under the action of the splicing unit. The splicing unit is clamped by the second curtain wall unit in a position opposite to the second curtain wall unit, so that the assembly stability is improved, and the splicing unit is fixed by the subsequent bolt matching so as to be convenient to install.

The foregoing description is only illustrative of the preferred embodiments of the present utility model and is not to be construed as limiting the scope of the utility model, and it will be appreciated by those skilled in the art that equivalent substitutions and obvious variations may be made using the description and illustrations of the present utility model, and are intended to be included within the scope of the present utility model.

Claims (10)

1. A novel curtain wall node, characterized by comprising:

the curtain wall system comprises a first curtain wall unit (100), wherein the first curtain wall unit (100) is vertically arranged;

a mounting unit (200), a first end of the mounting unit (200) being connected to the first curtain wall unit (100);

a splice unit (300), a first end of the splice unit (300) being connected to a second end of the mounting unit (200);

and the first end of the second curtain wall unit (400) is connected with the second end of the splicing unit (300).

2. The novel curtain wall node of claim 1, wherein the first curtain wall unit (100) comprises:

-a first fa sigmaade element (101), said first fa sigmaade element (101) being arranged vertically;

-a first positioning element (102), said first positioning element (102) being arranged horizontally through said first fa sigmaade element (101) and being connected to said mounting unit (200).

3. The novel curtain wall node according to claim 1, wherein the mounting unit (200) comprises:

-a first mounting element (201), said first mounting element (201) being connected to said first curtain wall unit (100);

a second positioning element (202), said second positioning element (202) being arranged on one side of said first mounting element (201) and being detachably connected to said first curtain wall unit (100);

the second installation element (203) is arranged on the rear side of the first curtain wall unit (100), and is detachably connected with the second positioning element (202) and the first curtain wall unit (100) respectively;

and the first fixing element (204) is respectively connected with the second installation element (203) and the wall body, and is used for fixing the first curtain wall unit (100) to the wall body.

4. A new curtain wall node according to claim 3, wherein the mounting unit (200) further comprises:

-a first connection element (205), the first connection element (205) being arranged through the first mounting element (201), the second positioning element (202);

-a second connection element (206), said second connection element (206) being arranged on one side of said second mounting element (203);

-a second fixing element (207), said second fixing element (207) being connected to said first connecting element (205), said second connecting element (206), respectively.

5. The novel curtain wall node according to claim 1, wherein the splicing unit (300) comprises:

-a base element (301), the bottom end of the base element (301) being connected to the mounting unit (200);

a first splice element (302), the first splice element (302) being disposed at a top end of the base element (301) and being connected to a first end of the second curtain wall unit (400);

-a chamber element (303), said chamber element (303) being arranged inside said base element (301) and being in communication with said first splicing element (302);

a first movable element (304), wherein the first movable element (304) is slidably arranged in the chamber element (303) along the horizontal direction and is abutted with the first end of the second curtain wall unit (400);

the second movable element (305) is slidably arranged in the chamber element (303) along the vertical direction and is abutted with the first movable element (304) so as to drive the first movable element (304) to reciprocate along the horizontal direction.

6. The novel curtain wall node of claim 5, wherein the splice unit (300) further comprises:

-a first sliding element (306), the first sliding element (306) being arranged inside the chamber element (303);

-a second sliding element (307), said second sliding element (307) being connected to said second movable element (305) and being slidingly connected to said first sliding element (306) for defining a direction of movement of said second movable element (305); and/or

-a driving element (308), said driving element (308) being connected to said second movable element (305) for driving said second movable element (305) to reciprocate in a vertical direction; and/or

-a third sliding element (309), the third sliding element (309) being arranged inside the chamber element (303);

-a fourth sliding element (310), said fourth sliding element (310) being connected to said first movable element (304) and being slidingly connected to said third sliding element (309) for defining a direction of movement of said first movable element (304).

7. The novel curtain wall node of claim 6, wherein the splice unit (300) further comprises:

-an elastic element (311), said elastic element (311) being connected to said third sliding element (309) and to said fourth sliding element (310), respectively.

8. The novel curtain wall node according to any one of claims 5 to 7, wherein the splicing unit (300) further comprises:

-a first locking element (312), said first locking element (312) being arranged on one side of said first movable element (304) and being in locking connection with a first end of said second curtain wall unit (400).

9. The novel curtain wall node of claim 1, wherein the second curtain wall unit (400) comprises:

-a second fa sigmaade element (401), said second fa sigmaade element (401) being arranged in the upper part of said splice-in unit (300);

-a second splice element (402), the second splice element (402) being arranged at a first end of the second fa sigmaade element (401) and being connected to the splice unit (300).

10. The novel curtain wall node of claim 9, wherein the second curtain wall unit (400) further comprises:

-a second locking element (403), which second locking element (403) is arranged on one side of the second splicing element (402) and is connected to the splicing unit (300) for securing the second fa sigmaade element (401) to the splicing unit (300).