Air conditioner condensate water recycling glass curtain wall device

By designing a water spray system on the glass curtain wall to collect and utilize air conditioning condensate for cooling, the problems of energy and water waste caused by glass curtain walls are solved, achieving efficient energy utilization and cooling effect.

CN116642263BActive Publication Date: 2026-06-19JIANGSU JINGTIAN CONSTR ENG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
JIANGSU JINGTIAN CONSTR ENG CO LTD
Filing Date
2023-07-03
Publication Date
2026-06-19

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  • Figure CN116642263B_ABST
    Figure CN116642263B_ABST
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Abstract

This application provides a glass curtain wall device for recycling and reusing air conditioning condensate, relating to the field of glass curtain walls. It includes several vertical grooves on the exterior facade of a building, with horizontal grooves for hanging glass panels spaced apart between adjacent vertical grooves. Several glass panels are fixed to form a glass curtain wall. Each of the vertical grooves is equipped with a water spray pipe, one end of which is located at the top of the building, and the other end is closed and extends to the bottom of the building. Several through holes are provided on the outer wall of the water spray pipe. A water storage tank is located at the top of the building, with an inlet pipe and an outlet pipe at the top of the tank. The outlet pipe is connected to one end of the water spray pipe. Air conditioning condensate flows into the water storage tank through the inlet pipe and is then pumped into the outlet pipe by a water pump and the inlet pipe. This application has the effect of reducing the unreasonable energy consumption or waste caused by the use of glass curtain walls.
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Description

Technical Field

[0001] This application relates to the field of glass curtain walls, and in particular to a glass curtain wall device for recycling and reusing air conditioning condensate. Background Technology

[0002] A glass curtain wall is a building envelope or decorative structure consisting of a supporting structural system that allows for a certain degree of displacement relative to the main structure and does not share the loads of the main structure. The wall can be single-layered or double-layered. Glass curtain walls are an aesthetically pleasing and innovative method of building wall decoration, and are one of the main elements of modern architectural design. They are currently widely used in various high-rise office buildings, high-rise residential buildings, and large commercial complexes.

[0003] Currently, it has been found that after prolonged exposure to sunlight, glass curtain walls can cause indoor temperatures to rise rapidly, requiring air conditioning to be turned on and the set temperature lowered to cool the room. This consumes a significant amount of extra energy. Therefore, spraying water onto the glass curtain wall at regular intervals can help reduce its temperature.

[0004] However, while water spraying can reduce the electricity consumption of air conditioning to some extent, the use of cooling water can easily lead to water waste. Moreover, during the operation of a large number of air conditioners, a lot of condensate will be generated. This low-temperature condensate is generally discharged directly through the drain pipe and is not effectively recycled and reused, thus still resulting in resource waste. Summary of the Invention

[0005] In order to improve the problem that glass curtain walls indirectly waste a lot of energy during use, this application provides a glass curtain wall device for recycling and reusing air conditioning condensate.

[0006] This application provides a glass curtain wall device for recycling and reusing air conditioning condensate, which adopts the following technical solution:

[0007] A glass curtain wall device for recycling and reusing air conditioning condensate includes several vertical grooves on the exterior facade of a building, with horizontal grooves for hanging glass panels spaced apart between adjacent vertical grooves. After the glass panels are fixed, a glass curtain wall is formed. Each of the vertical grooves is equipped with a water spray pipe, one end of which is located at the top of the building, and the other end is closed and extends to the bottom of the building. Several through holes are provided on the outer wall of the water spray pipe. A water storage tank is provided at the top of the building, and an inlet pipe and an outlet pipe are provided at the top of the water storage tank. The outlet pipe is connected to one end of the water spray pipe. The air conditioning condensate flows into the water storage tank through the inlet pipe and is then pumped into the outlet pipe by a water pump and the inlet pipe.

[0008] By adopting the above technical solution, the condensate generated during air conditioner operation is collected in a storage tank through the inlet pipe. When the glass curtain wall reaches a high temperature, the water pump is turned on, pumping the condensate from the storage tank into the spray pipe through the outlet pipe. Because the outer wall of the spray pipe has through holes, the pressurized condensate is sprayed out from these holes. By adjusting the water pump power, the condensate reliably flows into the spray pipe and is sprayed out from the through holes at a low speed. Thus, the sprayed condensate gradually moves downwards under the influence of gravity. During the descent, some of the air conditioning condensate will drift onto the glass curtain wall, cooling it down. Some will also form a water curtain, providing dust protection and heat insulation. This application collects the cooler air conditioning condensate and then sprays it onto the outside of the glass curtain wall to cool it down, thereby reducing the building's cooling demand and energy consumption. Furthermore, the recycling and reuse of the air conditioning condensate reduces the waste of water resources caused by external water sources directly cooling the glass curtain wall.

[0009] Preferably, the top height of the water storage tank is not higher than the top height of the building, and the exterior of the water storage tank is covered with an insulation layer.

[0010] By adopting the above technical solution, the condensate generated by the air conditioner can flow into the water storage tank by gravity without power, further reducing energy loss. Moreover, when the height of the water storage tank is low, the area and time of sunlight exposure to the water storage tank can be reduced, and the temperature rise of the condensate can be delayed to the greatest extent under the heat preservation effect of the insulation layer. This increases the temperature difference between the condensate and the glass curtain wall, thereby improving the cooling effect of the condensate on the glass curtain wall and reducing indirect energy loss caused by the heating of the glass curtain wall.

[0011] Preferably, the top of the building is also provided with a column-shaped water distributor, the water outlet pipe is connected to one side of the water distributor, and several of the water spray pipes are connected to the other side of the water distributor.

[0012] By adopting the above technical solution, the air conditioning condensate in the outlet pipe first enters the water distributor, and then flows into each spray pipe through the water distributor. This ensures that the air conditioning condensate can be sprayed evenly from several through holes in several spray pipes, avoiding a large amount of air conditioning condensate in the spray pipes near the outlet pipe and a small amount of air conditioning condensate in the spray pipes far from the outlet pipe, thereby improving the water spray cooling effect.

[0013] Preferably, the radial cross-section of the water spray pipe is square, the side of the water spray pipe with the through hole is flush with the opening of the vertical groove, and the other sidewalls of the water spray pipe are filled with sealant between them and the inner wall of the vertical groove.

[0014] By adopting the above technical solution, after the water spray pipe is placed into the vertical groove, the water spray pipe and the vertical groove can be filled and sealed with sealant to ensure that external rainwater and other debris will not enter the back of the glass curtain wall through the gaps between the glass panels, and also improve the firmness of the glass curtain wall assembly; since the water spray pipe is square, it can be more easily sealed in the vertical groove with sealant to prevent it from falling off.

[0015] Preferably, the water spray pipe is further provided with a plurality of water spray mechanisms, and the plurality of water spray mechanisms correspond one-to-one with the plurality of through holes;

[0016] The water spraying mechanism includes a sleeve, a piston, a water supply pipe, and a flow guide. The bottom of the sleeve is sealed with the through hole. The outer wall of the piston is fitted with the front inner wall of the sleeve and separated from the rear inner wall of the sleeve. One end of the water supply pipe is connected to the piston and has a water inlet communicating with the sleeve. The other end of the water supply pipe is connected to the flow guide through a bracket. The water supply pipe sprays water toward the concave inner wall of the flow guide.

[0017] By adopting the above technical solution and adjusting the power of the water pump, the water pressure in the spray pipe is increased, which in turn pushes the piston from the opening of the sleeve to the bottom of the sleeve. In this way, the air conditioning condensate enters the interior of the sleeve through the gap between the sleeve and the piston. Moreover, since there is a water inlet on the water supply pipe, the air conditioning condensate can enter the water supply pipe through the water inlet and then be sprayed out through the water supply pipe. Through the guiding effect of the flow guide, the angle between the air conditioning condensate and the glass curtain wall is reduced and the water flow after guidance is more dispersed, which can increase the amount of air conditioning condensate in contact with the glass curtain wall and be used for cooling, thereby improving the cooling effect.

[0018] Preferably, the water spraying mechanism further includes a spring, one end of which is connected to the inner wall of the water spray pipe, and the other end of which is connected to a piston.

[0019] By adopting the above technical solution, the spring is in a stretched state during the process of the air conditioner condensate pushing the piston and entering the sleeve. After the water spraying and cooling is completed, the spring contraction can pull the guide cover and piston back to the initial state.

[0020] Preferably, a bearing is fitted at the other end of the water supply pipe, one end of the bracket is connected to the outer ring of the bearing, and the other end of the bracket is connected to the inner wall of the flow guide.

[0021] By adopting the above technical solution, when there is a crosswind outside the building, the deflector can be turned, which can prevent the deflector and water pipe from bending and being damaged when the wind force is too strong.

[0022] Preferably, the inner wall of the flow guide is provided with a plurality of flow guide grooves, and the plurality of flow guide grooves are in a radiating shape extending from the center of the inner wall of the flow guide towards the surrounding edges.

[0023] By adopting the above technical solution, one end of several guide channels converges at the center of the inner wall of the guide shroud, while the other end of several guide channels disperses towards the periphery of the guide shroud. In this way, after the air conditioning condensate is sprayed out of the water pipe, the air conditioning condensate can change from a columnar shape to a surface shape under the guiding effect of several guide channels, and the whole is more dispersed, which significantly improves the cooling effect on the glass curtain wall and reduces the energy consumption in the building.

[0024] Preferably, the outer edge of the flow guide is provided with a rubber strip, and the inner wall of the through hole is provided with an annular groove, and the rubber strip is adapted to be locked in the groove.

[0025] By adopting the above technical solution, the rubber strip can only move out or enter the slot by deforming during the process of pushing out or pulling back the guide shroud of the water supply pipe. This can improve the sealing effect of the guide shroud on the through hole after reset, and prevent dust and other debris from entering the interior of the spray pipe through the gap between the guide shroud and the through hole, which could cause jamming during bearing rotation or jamming during the process of the water supply pipe entering and exiting the sleeve.

[0026] Preferably, the bottom of the sleeve is provided with a perforation, through which the water supply pipe extends to the outside of the sleeve, and the water inlet is always located inside the sleeve.

[0027] By adopting the above technical solution, the inlet is always located inside the sleeve during the displacement of the water supply pipe through the perforation. This ensures that the air conditioning condensate in the spray pipe can enter the water supply pipe through the inlet and then be sprayed out through the water supply pipe, thus ensuring the continuity and consistency of the air conditioning condensate output.

[0028] In summary, this application has the following beneficial effects:

[0029] 1. The condensate generated during the operation of the air conditioner is collected into the water storage tank through the water inlet pipe, realizing the recycling of the air conditioner condensate as waste and avoiding the waste of water resources caused by the direct discharge of air conditioner condensate.

[0030] 2. By pressurizing and pumping water, the air conditioning condensate in the storage tank is pumped into the spray pipe. After the air conditioning condensate in the spray pipe reaches a certain pressure, the piston is pushed to move, increasing the distance between the piston and the sleeve. This allows the air conditioning condensate to enter the water supply pipe through the inlet and spray onto the guide shroud. Under the guidance of the guide shroud, the columnar air conditioning condensate becomes mist, which improves the cooling effect on the glass curtain wall and reduces the energy waste or unreasonable losses indirectly caused by the installation of the glass curtain wall. Attached Figure Description

[0031] Figure 1 This is an illustrative three-dimensional representation of the present application. Figure 1 ;

[0032] Figure 2 This is an illustrative three-dimensional representation of the present application. Figure 2 ;

[0033] Figure 3 This is a schematic diagram of the internal structure of the water spray pipe in this application;

[0034] Figure 4 yes Figure 3 Reference diagram of the action state;

[0035] Figure 5 This is a schematic perspective view of the water supply pipe and the flow guide in this application;

[0036] In the diagram: 1. Building; 2. Vertical channel; 3. Glass plate; 4. Horizontal channel; 5. Spray pipe; 51. Through hole; 510. Slot; 6. Water tank; 61. Inlet pipe; 62. Outlet pipe; 63. Water pump; 64. Water distributor; 7. Spray mechanism; 71. Sleeve; 710. Perforation; 72. Piston; 73. Water supply pipe; 731. Inlet; 732. Support; 733. Bearing; 74. Flow guide; 741. Flow guide channel; 742. Rubber strip; 75. Spring. Detailed Implementation

[0037] The following is in conjunction with the appendix Figure 1-5 This application will be described in further detail.

[0038] Figure 1 This is an illustrative three-dimensional representation of the present application. Figure 1 , Figure 2 This is an illustrative three-dimensional representation of the present application. Figure 2 See also Figure 1 and Figure 2A glass curtain wall device for recycling and reusing air conditioning condensate includes several vertical grooves 2 and horizontal grooves 4 that intersect to form a grid on the exterior facade of a building 1. The vertical grooves 2 are unobstructed vertically, and the two ends of the horizontal grooves 4 are respectively connected to two adjacent vertical grooves 2. Each grid contains a glass panel 3, and several glass panels 3 constitute a glass curtain wall. An outdoor unit for an air conditioner is installed on the top of building 1. The outdoor unit discharges condensate water from the top of building 1. A water storage tank 6 is also installed on the top of building 1. The water storage tank 6 has an inlet pipe 61 and an outlet pipe 62. The top of the water storage tank 6 is lower than the top of building 1. Specifically, the inlet height of the inlet pipe 61 on the water storage tank 6 is lower than the discharge height of the condensate water from the outdoor unit. This ensures that the condensate water can enter the inlet pipe 61 without external power and be collected in the water storage tank 6, avoiding direct discharge or overflow of water resources. In order to reduce the temperature rise rate after the condensate water is discharged, the water storage tank 6 can be located inside building 1 and an insulation layer can be wrapped around the outer wall of the water storage tank 6 (using an insulation layer to wrap an object to achieve insulation is existing technology, so the specific structure of the insulation layer is not shown in the figure). In this way, the cooling effect on the glass curtain wall can be maximized after the condensate water is discharged.

[0039] Figure 3 This is a schematic diagram of the internal structure of the water spray pipe 5 in this application. See also... Figure 3 A square-section water spray pipe 5 is installed in each of the vertical troughs 2. The water spray pipe 5 is sealed to the vertical trough 2 with sealant. Because the water spray pipe 5 is square, it can be sealed more firmly in the vertical trough 2. Several through holes 51 are provided on each water spray pipe 5. Several water spraying mechanisms 7 are provided in each water spray pipe 5, corresponding to the through holes 51. The water spraying mechanism 7 includes a sleeve 71, a piston 72, a water supply pipe 73, a guide shroud 74, and a spring 75. The bottom of the sleeve 71 is covered with the through hole 51. The bottom of the sleeve 71 has a through hole 710 coaxial with the through hole 51. One end of the water supply pipe 73 is located in the sleeve 71, and the other end extends to the spray pipe through the through hole 710. The inner diameter of the sleeve 71 at the opening of the water pipe 5 is smaller than the inner diameter at the bottom of the sleeve 71. The piston 72 is adapted to the opening of the sleeve 71 and slides at the opening of the sleeve 71. That is to say, the sleeve 71 is a variable diameter component. When the piston 72 is located at the opening of the sleeve 71, the piston 72 and the sleeve 71 are in close contact with each other to achieve a reliable seal on the sleeve 71. When the piston 72 is located at the bottom of the sleeve, the piston 72 and the sleeve 71 are separated from each other, and the sleeve 71 is in an open state. One end of the water pipe 73 is connected to the piston 72, and the other end is connected to the guide shroud 74 through the bracket 732. The spring 75 is located between the piston 72 and the inner wall of the water spray pipe 5.

[0040] Figure 4 yes Figure 3The diagram shows the action state. See also... Figure 4 The water pump 63 pumps the air conditioning condensate from the water storage tank 6 into the water distributor 64 at the top of the building 1 through the outlet pipe 62. Since one side of the water distributor 64 is connected to the outlet pipe 62 and the other side is connected to several spray pipes 5, the air conditioning condensate in the water distributor 64 will evenly enter each spray pipe 5. Moreover, the water pressure of the air conditioning condensate in the spray pipe 5 is relatively high, which will push the piston 72 from the opening of the sleeve 71 to the bottom of the sleeve 71. When the piston 72 moves to a position close to the bottom of the sleeve 71, the piston 72 is in a suspended state, that is, the outer wall of the piston 72 is separated from the inner wall of the sleeve 71. In this way, the air conditioning condensate in the spray pipe 5 The condensate can flow to the side where the piston 72 is connected to the water supply pipe 73. One end of the water supply pipe 73 is provided with an inlet 731. The air conditioning condensate will enter the water supply pipe 73 through the inlet 731 and finally spray out from the other end of the water supply pipe 73. The sprayed air conditioning condensate can cool the glass curtain wall, which can reduce the demand for air conditioning in the building 1. In other words, the air conditioning in the building 1 can reduce energy consumption. By recycling the air conditioning condensate that was originally directly discharged and using the recycled air conditioning condensate to cool the glass curtain wall, the indirect energy consumption caused by the installation of the glass curtain wall can be reduced, effectively avoiding energy waste.

[0041] During the displacement of the piston 72 and water pipe 73 caused by the air conditioning condensate, the spring 75 is in a stretched state. This serves two purposes: firstly, it limits the displacement of the water pipe 73, ensuring that the inlet 731 on the water pipe 73 remains within the sleeve 71; secondly, it resets the guide shroud 74, water pipe 73, and piston 72 after the water spraying and cooling process is complete. Furthermore, by adjusting the spring constant of the spring 75, the displacement of the piston 72, water pipe 73, and guide shroud 74 can be controlled. This ensures that when the building 1 is high, the water spraying mechanisms 7 at higher and lower locations spray air conditioning condensate at the same or similar water pressure, avoiding a large pressure difference due to height differences, which would reduce the uniformity of water spraying from each spraying mechanism 7. Moreover, the guide shroud 74 guides the columnar air conditioning condensate... During the diversion process, a small amount of air conditioning condensate will be reflected onto the bearing 733 and the water pipe 73, achieving a backwashing effect on the bearing 733 and the water pipe 73. This prevents excessive dust from adhering to the guide cover 74 and the water pipe 73 after they are extended, which could cause the bearing 733 to rotate poorly or the water pipe 73 to get stuck between the sleeve 71. In this way, the backwashing effect ensures that the water pipe 73 can reliably extend or retract, thereby pushing the guide cover 74. The guide cover 74 then diverts the air conditioning condensate. It also ensures that the bearing 733 can support the guide cover 74 to rotate when it is blown by crosswinds, thus preventing the water pipe 73 from breaking due to excessive reaction force between the crosswind and the guide cover 74. This ensures that the guide cover 74 can reliably divert and disperse the air conditioning condensate.

[0042] Figure 5 This is a schematic perspective view of the water supply pipe 73 and the flow guide shroud 74 in this application. See also Figure 5Because the water supply pipe 73 is equipped with a bearing 733, the water supply pipe 73 and the inner ring of the bearing 733 are interference-fitted, and the outer ring of the bearing 733 is equipped with a bracket 732, which is connected to the guide shroud 74, so that there is a distance between the other end face of the water supply pipe 73 and the recessed inner wall of the guide shroud 74. The air conditioning condensate in the water supply pipe 73 is sprayed out through the gap between the water supply pipe 73 and the guide shroud 74. The inner wall of the guide shroud 74 is equipped with several guide grooves 741. One end of the several guide grooves 741 converges at the center of the inside of the guide shroud 74, and the other end of the several guide grooves 741 diverges towards the periphery of the guide shroud 74. When there is a crosswind outside the building 1, with the cooperation of the support 732 and the bearing 733, the guide shroud 74 with a large force-bearing area can rotate under the blowing of the crosswind, thereby preventing the crosswind from generating a large interaction force between the crosswind and the guide shroud 74, which could cause the water pipe 73 to break. This ensures that the guide shroud 74 can reliably guide and disperse the air conditioning condensate sprayed from the water pipe 73, thereby increasing the contact area between the air conditioning condensate and the glass plate 3, which in turn improves the cooling effect of the air conditioning condensate on the glass plate 3, and minimizes the additional energy consumption or waste caused by the installation of the glass curtain wall.

[0043] See Figure 4 and Figure 5 When the air conditioner condensate sprays out from the water pipe 73, the columnar water flow impacts the center of the guide shroud 74. The center of the guide shroud 74 has several guide channels 741. After impacting the guide shroud 74, the air conditioner condensate flows along the arc of the guide channels 741. Since the guide channels 741 are divergent, the columnar air conditioner condensate is dispersed into a surface under the guidance of the guide channels 741. The flow angle of the air conditioner condensate can be adjusted to prevent it from flying away from the glass curtain wall. This ensures that most of the air conditioner condensate can directly act on the glass curtain wall, significantly reducing the temperature of the glass curtain wall. A small portion of the air conditioner condensate can form a water curtain on the outside of the glass curtain wall, which can be used to block dust and provide some heat insulation.

[0044] See Figure 5The outer edge of the flow guide shroud 74 is provided with a rubber strip 742, and the inner wall of the through hole 51 is provided with an annular groove 510, in which the rubber strip 742 is fitted. Under the action of the piston 72 and the water pipe 73, the flow guide shroud 74 will repeatedly move in and out of the through hole 51. During this process, the rubber strip 742 on the outer edge of the flow guide shroud 74 will undergo elastic deformation, thereby ensuring that the flow guide shroud 74 can disengage from the groove 510 and extend, thus reliably dispersing and guiding the air conditioning condensate. It also ensures that after the rubber strip 742 is fitted into the groove 510 through elastic deformation, the groove 510 and the rubber strip 742 are tightly connected, and the rubber strip 742 completely seals the through hole 51, preventing external debris from entering the sleeve 71 or the spray pipe 5.

[0045] The specific working process of this application is as follows: the air conditioning condensate generated during the operation of the air conditioner is collected into the water storage tank 6 through the water inlet pipe 61. When the temperature of the glass curtain wall rises under the sun, the water pump 63 is turned on, and the air conditioning condensate pump 63 in the water storage tank 6 is pumped into the water distributor 64 through the water outlet pipe 62. Then the water distributor 64 distributes the air conditioning condensate to all the spray pipes 5.

[0046] When the water pressure of the air conditioner condensate in the spray pipe 5 increases, it will push the piston 72 to move, so that the piston 72 and the sleeve 71 change from a tightly fitted state to a mutually separated state, so that the air conditioner condensate can enter the water supply pipe 73 through the water inlet 731, and then be sprayed through the water supply pipe 73 to the guide shroud 74.

[0047] The inner wall of the deflector 74 is provided with several diverging deflector channels 741. After the air conditioning condensate impacts the deflector 74, it will disperse into the deflector channels 741 and fly out along the periphery of the deflector 74 under the guiding action of the deflector channels 741. This will change the air conditioning condensate from a columnar water flow to a surface water mist, thus realizing the use of waste air conditioning condensate to cool the glass curtain wall, thereby reducing energy consumption or waste.

[0048] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.

Claims

1. A glass curtain wall device for recycling and reusing air conditioning condensate, comprising a plurality of vertical grooves (2) provided on the exterior facade of a building (1), and horizontal grooves (4) for hanging glass panels (3) spaced apart between adjacent vertical grooves (2), wherein the plurality of glass panels (3) are fixed to form a glass curtain wall, characterized in that, Each of the vertical troughs (2) is provided with a water spray pipe (5), one end of which is located at the top of the building (1), and the other end is closed and extends to the bottom of the building (1). The outer wall of the water spray pipe (5) is provided with several through holes (51). The building (1) is equipped with a water storage tank (6) on its top. The water storage tank (6) is equipped with an inlet pipe (61) and an outlet pipe (62) on its top. The outlet pipe (62) is connected to one end of a spray pipe (5). Air conditioning condensate flows into the water storage tank (6) through the inlet pipe (61) and is then pumped into the outlet pipe (62) through the water pump (63) and the inlet pipe (61). The radial cross section of the water spray pipe (5) is square. The side of the water spray pipe (5) with the through hole (51) is flush with the opening of the vertical groove (2). The other side walls of the water spray pipe (5) are filled with sealant between them and the inner wall of the vertical groove (2). The water spray pipe (5) is also provided with a plurality of water spray mechanisms (7), and the plurality of water spray mechanisms (7) correspond one-to-one with the plurality of through holes (51); The water spraying mechanism (7) includes a sleeve (71), a piston (72), a water supply pipe (73), and a flow guide (74). The bottom of the sleeve (71) is sealed with the through hole (51). The outer wall of the piston (72) is in contact with the front inner wall of the sleeve (71) and is separated from the rear inner wall of the sleeve (71). One end of the water supply pipe (73) is connected to the piston (72) and has a water inlet (731) communicating with the sleeve (71). The other end of the water supply pipe (73) is connected to the flow guide (74) through a bracket (732). The water supply pipe (73) sprays water toward the recessed inner wall of the flow guide (74). The water spraying mechanism (7) also includes a spring (75), one end of which is connected to the inner wall of the water spray pipe (5), and the other end of which is connected to the piston (72).

2. The glass curtain wall device for recycling condensate water of an air conditioner according to claim 1, characterized in that, The top height of the water storage tank (6) is not higher than the top height of the building (1), and the exterior of the water storage tank (6) is covered with an insulation layer.

3. A glass curtain wall device for recycling and reusing air conditioning condensate according to claim 1, characterized in that, The top of the building (1) is also provided with a water distributor (64), the water outlet pipe (62) is connected to one side of the water distributor (64), and several of the water spray pipes (5) are connected to the other side of the water distributor (64).

4. A glass curtain wall device for recycling and reusing air conditioning condensate according to claim 1, characterized in that, The other end of the water pipe (73) is fitted with a bearing (733), one end of the bracket (732) is connected to the outer ring of the bearing (733), and the other end of the bracket (732) is connected to the inner wall of the guide shroud (74).

5. A glass curtain wall device for recycling and reusing air conditioning condensate according to claim 4, characterized in that, The inner wall of the flow guide shroud (74) is provided with a plurality of flow guide grooves (741), and the plurality of flow guide grooves (741) are in a divergent shape extending from the center of the inner wall of the flow guide shroud (74) toward the surrounding edges.

6. A glass curtain wall device for recycling and reusing air conditioning condensate according to claim 5, characterized in that, The outer edge of the flow guide (74) is provided with a rubber strip (742), and the inner wall of the through hole (51) is provided with an annular groove (510). The rubber strip (742) is adapted to be fitted in the groove (510).

7. A glass curtain wall device for recycling and reusing air conditioning condensate according to any one of claims 2-6, characterized in that, The bottom of the sleeve (71) is provided with a perforation (710), and the water pipe (73) passes through the perforation (710) to the outside of the sleeve (71). The water inlet (731) is always located inside the sleeve (71).