CN213626215U - Green energy-saving glass curtain wall - Google Patents

Abstract

The utility model discloses a green energy-saving glass curtain wall, which comprises an inner curtain wall, an outer curtain wall is arranged on the right side of the inner curtain wall, window frames are fixedly connected around the inner curtain wall and the outer curtain wall, a support column is fixedly connected on the right side wall of the inner curtain wall, a support plate a is welded on the right side wall of the support column, a support plate b is welded on the upper surface of the support plate a, a chute a is arranged in the middle of the upper surface of the support plate b, a slide block a is connected in the chute a in a sliding way, a motor is fixedly connected on the upper surface of the slide block a, a fixed plate is welded at the outlet end of the motor, a slide groove b is arranged on the front surface of the fixed plate, a slide block b is connected in the chute b in a sliding way, a baffle is welded on the front surface of the lower end of the, preventing rainwater from entering the channel through the air outlet.

Description

Green energy-saving glass curtain wall

Technical Field

The utility model relates to a green energy-saving glass curtain wall technical field, more specifically say, relate to a green energy-saving glass curtain wall.

Background

The glass curtain wall is a building external protective structure or a decorative structure which has a certain displacement capacity relative to the main structure by a supporting structure system and does not bear the action of the main structure. The wall body has two types of single-layer glass and double-layer glass. The glass curtain wall is a beautiful and novel building wall decoration method and is a remarkable characteristic of modern high-rise building times.

At present, curtain walls are mostly arranged into double-layer curtain walls to achieve the effects of energy conservation and emission reduction, and a relatively closed space is formed between the inner curtain wall and the outer curtain wall. The lower part of the outer curtain wall is provided with an air inlet, the upper part of the outer curtain wall is provided with an air outlet, the flowing state of air can be controlled between the outer curtain wall and the air outlet, and the inner curtain wall is generally provided with an inward opening window to achieve the ventilation effect. In summer, the temperature in the ventilation channel in the middle of the double-layer curtain wall is very high, the air outlets and the air inlets at the upper end and the lower end of the ventilation channel can be opened, airflow from bottom to top is generated in the ventilation pipeline due to a thermal chimney effect (the phenomenon that the air is forced to flow convectively because the air rises or falls along a space with a vertical gradient), the airflow entering from the lower air inlet is ventilated in the double-layer, and is exhausted from the upper air outlet after heat exchange, and the airflow from bottom to top moves to take away the heat in the channel, reduce the temperature of the outer surface of the inner-layer curtain wall, reduce the load of air-conditioning refrigeration, save energy and reduce energy consumption; in winter, the temperature of the ventilation channel in the middle of the double-layer curtain wall rises due to the irradiation of sunlight, and a greenhouse effect (a heat preservation effect formed by lack of heat exchange between the closed space transmitting sunlight and the outside) is formed. Thus being beneficial to improving the surface temperature of the inner curtain wall and reducing the operation cost of the building due to winter heating.

However, when raining, rainwater easily flows into the space between the inner curtain wall and the outer curtain wall from the air outlet, even flows into the room, and causes indoor moisture.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a green energy-saving glass curtain wall aims at the problem that can be effectual among the solution prior art.

In order to solve the above problem, the utility model adopts the following technical scheme:

a green energy-saving glass curtain wall comprises an inner curtain wall, wherein an outer curtain wall is arranged on the right side of the inner curtain wall, window frames are fixedly connected to the peripheries of the inner curtain wall and the outer curtain wall, a support column is fixedly connected to the right side wall of the inner curtain wall, a support plate a is welded to the right side wall of the support column, a support plate b is welded to the upper surface of the support plate a, a sliding groove a is formed in the middle of the upper surface of the support plate b, a sliding block a is connected to the sliding groove a in a sliding mode, a motor is fixedly connected to the upper surface of the sliding block a, a fixed plate is welded to the outlet end of the motor, a sliding groove b is arranged on the front surface of the fixed plate, a sliding block b is connected to the sliding groove b in a sliding mode, a baffle is, the moving of the sliding block b drives the baffle to turn over, so that the baffle is just clamped in the air inlet and the air outlet, and rainwater is prevented from entering the channel through the air outlet.

As a preferred scheme of the utility model, spout a's upper surface left part fixedly connected with cylinder, the exit end of cylinder and slider a's left side wall middle part welding are in the same place.

As a preferred scheme of the utility model, the right side wall lower part of outer curtain wall is provided with the air inlet tripe, the right side wall upper portion of outer curtain wall is provided with the air outlet, the baffle matches each other with the air outlet.

As a preferred scheme of the utility model, backup pad a is the L shape, the front welding of baffle has a pair of fixed column a, a pair of fixed column a's below is provided with a pair of otic placode a, the back welding of baffle has a pair of fixed column b, a pair of fixed column b's below is provided with a pair of otic placode b.

As a preferred scheme of the utility model, a pair of otic placode an and a pair of otic placode b all weld on backup pad an's upper surface, a pair of otic placode an all is provided with recess b with a pair of otic placode b's upper end, recess b is the arc wall, a pair of fixed column an, a pair of fixed column b all match each other with recess b.

As an optimized scheme of the utility model, recess an is opened to backup pad a's upper surface, recess an is located the baffle under, the left side wall of baffle is provided with the bleeder vent.

Compared with the prior art, the utility model has the advantages of:

(1) all be provided with the strengthening rib in support column and backup pad an, the bearing capacity of support column and backup pad a has been improved, the motor is the motor that just reverses, the exit end welding of motor has the fixed plate, the front of fixed plate is provided with spout b, sliding connection has slider b in the spout b, the welding of slider b's lower extreme front has the baffle, the starter motor drive fixed plate rotates, the rotation of fixed plate drives slider b and slides in spout b, slider b's removal drives the baffle and overturns.

(2) The air inlet tripe is triangle-shaped, and the air inlet tripe is cut to one side towards the right of outer curtain, can realize the heat in the interchange passageway, simultaneously, in can preventing rainwater entering passageway, the baffle matches each other with the air outlet, when raining, through mutually supporting between cylinder and the motor, the drive baffle overturns to in making the baffle just in time block business turn over wind gap, prevent that the rainwater from passing through in the air outlet entering passageway.

Drawings

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is an enlarged schematic view of a structure at a point a in fig. 1 according to the present invention;

fig. 3 is a schematic top view of the present invention.

The reference numbers in the figures illustrate:

1. an outer curtain wall; 2. a window frame; 3. an inner curtain wall; 4. air inlet shutter; 5. an air outlet; 6. a support pillar; 7. a support plate a; 8. air holes are formed; 9. a pair of ear plates a; 10. a pair of ear plates b; 11. a pair of fixed columns a; 12. a pair of fixing posts b; 13. a baffle plate; 14. a support plate b; 15. a groove a; 16. a groove b; 17. a chute a; 18. a cylinder; 19. a slide block a; 20. a motor; 21. a fixing plate; 22. a chute b; 23. and a slide block b.

Detailed Description

The technical solution in the embodiment of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiment of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention based on the embodiments of the present invention.

Example (b):

referring to fig. 1-3, the green energy-saving glass curtain wall comprises an inner curtain wall 3, an outer curtain wall 1 is arranged on the right side of the inner curtain wall 3, window frames 2 are fixedly connected to the peripheries of the inner curtain wall 3 and the outer curtain wall 1, a support pillar 6 is fixedly connected to the right side wall of the inner curtain wall 3, a support plate a7 is welded to the right side wall of the support pillar 6, a support plate b14 is welded to the upper surface of the support plate a7, a sliding groove a17 is arranged in the middle of the upper surface of the support plate b14, a sliding block a19 is slidably connected to the sliding groove a17, a motor 20 is fixedly connected to the upper surface of the sliding block a19, a fixing plate 21 is welded to the outlet end of the motor 20, a sliding groove b22 is arranged on the front surface of the fixing plate 21, a sliding block b23 is slidably connected to the sliding.

In this embodiment, in order to improve the bearing capacity of support column 6 and backup pad a7, all be provided with the strengthening rib in support column 6 and backup pad a7, motor 20 is the motor that rotates in the positive and negative direction, the exit end welding of motor 20 has fixed plate 21, the front of fixed plate 21 is provided with spout b22, sliding connection has slider b23 in spout b22, the front welding of the lower extreme of slider b23 has baffle 13, starter motor 20 drives fixed plate 21 and rotates, the rotation of fixed plate 21 drives slider b23 and slides in spout b22, the removal of slider b23 drives baffle 13 and overturns.

Specifically, the left part of the upper surface of the sliding chute a17 is fixedly connected with an air cylinder 18, and the outlet end of the air cylinder 18 is welded with the middle part of the left side wall of the sliding block a 19.

In this embodiment, the starting cylinder 18 can drive the sliding block a19 to slide in the sliding groove a17, the sliding block a19 can drive the motor 20 to move, and the sliding block b23 and the sliding groove b22 are matched with each other, so that the movement of the motor 20 can drive the baffle 13 to move.

Specifically, the right side wall lower part of outer curtain wall 1 is provided with air inlet tripe 4, the right side wall upper portion of outer curtain wall 1 is provided with air outlet 5, baffle 13 matches each other with air outlet 5.

In this embodiment, air inlet tripe 4 is triangle-shaped, and air inlet tripe 4 is cut to one side towards the right of outer curtain 1, can realize the heat in the interchange passageway, simultaneously, in can preventing rainwater entering channel, baffle 13 and air outlet 5 match each other, when raining, through mutually supporting between cylinder 18 and the motor 20, drive baffle 13 overturns to make baffle 13 just in time block in air outlet 5, prevent that the rainwater from passing through in the air outlet 5 access channel.

Specifically, the supporting plate a7 is L-shaped, a pair of fixing posts a11 are welded to the front of the baffle 13, a pair of ear plates a9 are arranged below the pair of fixing posts a11, a pair of fixing posts b12 are welded to the back of the baffle 13, a pair of ear plates b10 are arranged below the pair of fixing posts b12, the pair of ear plates a9 and the pair of ear plates b10 are both welded to the upper surface of the supporting plate a7, grooves b16 are respectively arranged at the upper ends of the pair of ear plates a9 and the pair of ear plates b10, the grooves b16 are arc-shaped grooves, and the pair of fixing posts a11 and the pair of fixing posts b12 are both matched with the grooves b 16.

In this embodiment, the groove b16 is an arc-shaped groove, the pair of fixing posts a11 and the pair of fixing posts b12 are matched with the groove b16, and the baffle 13 can be turned over on the pair of ear plates a9 and the pair of ear plates b10 by the mutual matching between the pair of fixing posts a11 and the pair of fixing posts b12 and the pair of ear plates a9 and the pair of ear plates b 10.

Specifically, the upper surface of the supporting plate a7 is provided with a groove a15, the groove a15 is located right below the baffle 13, and the left side wall of the baffle 13 is provided with an air hole 8.

In this embodiment, in order to prevent the device from affecting the heat exchange in the channel, the upper surface of the supporting plate a7 is provided with a groove a15, and the left side wall of the baffle 13 is provided with a ventilation hole 8.

The motor 20 is a conventional device, and the present application is only applied, and the working principle and the electrical connection relationship thereof belong to the prior art, so that the details are not repeated.

The working principle is as follows:

starting cylinder 18 can drive slider a19 and slide in spout a17, slider a 19's removal can drive motor 20 and remove, mutually support between slider b23 and spout b22, motor 20's removal can drive baffle 13 and remove, and simultaneously, starting motor 20 drives fixed plate 21 and rotates, fixed plate 21's rotation drives slider b23 and slides in spout b22, slider b 23's removal drives baffle 13 and overturns, thereby make baffle 13 just in time block in air outlet 5, prevent that the rainwater from passing through in the air outlet 5 access passage.

The above description is only the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can substitute or change the technical solution and the improvement concept of the present invention within the technical scope disclosed in the present invention.

Claims (6)

1. The utility model provides a green energy-saving glass curtain wall, includes inlayer curtain (3), the right side of inlayer curtain (3) is provided with outer curtain (1), inlayer curtain (3) and outer curtain (1) equal fixedly connected with window frame (2) all around, its characterized in that: fixedly connected with support column (6) on the right side wall of inlayer curtain (3), the welding has backup pad a (7) on the right side wall of support column (6), the upper surface welding of backup pad a (7) has backup pad b (14), the upper surface middle part of backup pad b (14) is provided with spout a (17), sliding connection has slider a (19) in spout a (17), the last fixed surface of slider a (19) is connected with motor (20), the exit end welding of motor (20) has fixed plate (21), the front of fixed plate (21) is provided with spout b (22), sliding connection has slider b (23) in spout b (22), the lower extreme front welding of slider b (23) has baffle (13).

2. The green energy-saving glass curtain wall as claimed in claim 1, wherein: the left part of the upper surface of the sliding chute a (17) is fixedly connected with an air cylinder (18), and the outlet end of the air cylinder (18) is welded with the middle part of the left side wall of the sliding block a (19).

3. The green energy-saving glass curtain wall as claimed in claim 1, wherein: the air inlet shutter is arranged on the lower portion of the right side wall of the outer curtain wall (1), the air outlet (5) is arranged on the upper portion of the right side wall of the outer curtain wall (1), and the baffle (13) is matched with the air outlet (5) mutually.

4. The green energy-saving glass curtain wall as claimed in claim 1, wherein: the supporting plate a (7) is L-shaped, a pair of fixing columns a (11) is welded to the front of the baffle plate (13), a pair of ear plates a (9) is arranged below the pair of fixing columns a (11), a pair of fixing columns b (12) is welded to the back of the baffle plate (13), and a pair of ear plates b (10) is arranged below the pair of fixing columns b (12).

5. The green energy-saving glass curtain wall as claimed in claim 4, wherein: the pair of ear plates a (9) and the pair of ear plates b (10) are welded on the upper surface of the supporting plate a (7), grooves b (16) are formed in the upper ends of the pair of ear plates a (9) and the pair of ear plates b (10), the grooves b (16) are arc-shaped grooves, and the pair of fixing columns a (11) and the pair of fixing columns b (12) are matched with the grooves b (16) mutually.

6. The green energy-saving glass curtain wall as claimed in claim 1, wherein: the upper surface of backup pad a (7) is opened flutedly a (15), recess a (15) are located baffle (13) under, the left side wall of baffle (13) is provided with bleeder vent (8).

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