WO2018028519A1

WO2018028519A1 - Integrated smart thermostatic ecological curtain wall system and temperature control method

Info

Publication number: WO2018028519A1
Application number: PCT/CN2017/096084
Authority: WO
Inventors: 冯华国
Original assignee: 金粤幕墙装饰工程有限公司
Priority date: 2016-08-09
Filing date: 2017-08-04
Publication date: 2018-02-15
Also published as: CN106245831A

Abstract

An integrated smart thermostatic ecological curtain wall system and a temperature control method. The system comprises an inner glass curtain wall (1), an outer glass curtain wall (2), a temperature control unit, an environment monitoring system, and an independent hollow layer (3) formed between the inner glass curtain wall (1) and the outer glass curtain wall (2). The temperature control unit is connected into the hollow layer (3). An air vent is formed in each of the inner glass curtain wall (1) and the outer glass curtain wall (2). Smart temperature control is implemented by smartly selecting a working mode, and the temperature of the hollow layer (3) is kept at a constant value at far as possible while energy consumption is reduced.

Description

Integrated intelligent constant temperature ecological curtain wall system and temperature control method

Technical field

The invention relates to a curtain wall system, in particular to an integrated intelligent constant temperature ecological curtain wall system and a temperature control method.

Background technique

With the improvement of living standards, people's requirements for the comfort of office space are also constantly increasing. How to minimize the operating cost of the air conditioning system on the basis of satisfying the comfort has been a serious problem that plagues the construction industry. The survey shows that the cold source in public places is still widely used, and the centralized air conditioner is running at full capacity, resulting in a large amount of energy waste. Generally, the closer to the air conditioning vent, the lower the temperature, making people uncomfortable and easy to generate air conditioning. disease.

In addition, although the market has begun to use the traditional ventilation window as a retaining structure, it can indeed take away a certain amount of solar radiant heat through natural ventilation and passive heat dissipation, but the ventilation effect is limited by the environment and building size factors. The actual heat taken away is limited.

Chinese Patent Application No. 201410748402.X discloses a three-layer glass structure composite temperature control curtain wall and a temperature control method thereof. The inner glass curtain wall and the outer glass curtain wall have electric louver panes on the upper and lower ends of the invention. a grid tuyere assembly; an inner side interlayer heat exchange channel is formed between the inner glass curtain wall and the middle partitioned glass curtain wall; a separate outer interlayer heat exchange channel is formed between the outer glass curtain wall and the middle partitioned fault glass curtain wall; and the middle partition glass curtain wall The semiconductor thermoelectric temperature control unit is uniformly distributed on the upper; the environmental monitoring system is composed of a plurality of temperature sensors, and provides real-time temperature monitoring data of the target environment for the temperature reading module in the single-chip control module; the semiconductor thermoelectric temperature control unit is controlled by the single-chip microcomputer control module .

The patent discloses the working condition of the curtain wall in summer. When the ambient temperature is higher than 28 degrees Celsius, the outer glass damper is opened, the inner glass damper is closed, and the cooling mode is turned on. First, since the outer glass is an ordinary single-layer glass. Therefore, the heat radiation in the outer interlayer ventilation channel is strong, which will increase the temperature of the partition layer and affect the temperature of the inner interlayer air passage, so that the temperature of the inner interlayer air passage increases, and the cooling power consumption of the semiconductor increases; secondly, when starting In the cooling mode, the temperature of the inner interlayer is lower than the outdoor temperature, and the external sunlight will increase the temperature of the outer interlayer. Especially when the middle glass is a single layer of glass, the inner interlayer cold air is more easily affected by the outdoor temperature, resulting in refrigeration function. The increase is important; the important part is that the curtain wall system glass is separated. When the curtain wall system is needed, the inner beam and the column need to be installed first, then the inner glass curtain wall is all installed on the building, and then the outer beam and column are installed. And the outer glass curtain wall, so the installation is more troublesome, and the energy saving effect of the curtain wall Ideal and install more trouble.

Summary of the invention

An object of the present invention is to provide an integrated intelligent constant temperature ecological curtain wall system, which has more energy saving and installation. More convenient advantages.

The above technical object of the present invention is achieved by the following technical solutions:

An integrated intelligent constant temperature ecological curtain wall system, comprising an integrated unit module, the unit module is installed on the outer wall of the building, the unit module comprises an inner glass curtain wall and an outer glass curtain wall, and the inner glass curtain wall And forming a hollow wall between the outer glass curtain wall and the solar power generation device, the intelligent constant temperature ecological curtain wall system further comprises a single chip, wherein the single chip is coupled with:

a hollow layer temperature sensor, disposed in the hollow layer, for detecting the temperature of the hollow layer and outputting a temperature signal Tm;

The temperature control unit is disposed on the curtain wall mounting structure in the hollow layer, and is controlled by the single-chip microcomputer to implement a cooling mode or a heating mode to adjust the temperature of the hollow layer to maintain the temperature of the hollow layer at the preset temperature signal Tx. The solution comprises: when the temperature of the hollow layer is detected by the hollow layer temperature sensor, and outputting the temperature signal Tm of the hollow layer, compared with the preset temperature Tx in the single chip, when the temperature Tm of the hollow layer is lower than the preset temperature Tx, the single chip microcomputer controls the temperature control unit to perform Heating until the hollow layer temperature Tm is equal to the preset temperature Tx, the heating operation is stopped, and only the airflow is exchanged;

When the temperature sensor of the hollow layer detects the temperature of the hollow layer and outputs the temperature signal Tm of the hollow layer, compared with the preset temperature Tx in the single chip microcomputer, when the temperature Tm of the hollow layer is higher than the preset temperature Tx, the single chip microcomputer controls the temperature control unit to perform cooling until the temperature is controlled. The hollow layer temperature Tm is equal to the preset temperature Tx, and the heating operation is stopped; the cycle is repeated to ensure that the temperature of the hollow layer is at the preset temperature Tx.

By adopting the above technical solution, the unit module is integrally installed around the building, and can be completed by one frame installation and one glass installation, and the prior art needs to be the first inside. After the installation of the glass curtain wall, the installation of the outer glass curtain wall is installed, which makes the installation of the curtain wall system more convenient. In addition, the decoration of the curtain wall system around the building is equivalent to adding a layer of constant temperature insulation layer to the building. Effectively prevent the loss of heat in the room. Because the outer glass curtain wall is double-glazed, it can effectively reduce the radiation of the sun in the summer, effectively blocking the heat from entering the hollow layer, thereby reducing the cooling power consumption of the hollow layer, while the inner glass The arrangement of the single-layer glass also allows the heat in the hollow layer to be transferred to the room without further transmission to the outdoor to further reduce the cooling power consumption; when the outdoor temperature is low in winter, the effect of the double-layer glass can also be effectively Good insulation effect, forming a greenhouse effect in the hollow layer, which can reduce the work of heating ; Presence isothermal holding barrier layer may influence the indoor temperature of the outdoor temperature, so that the indoor temperature can be kept at a certain temperature, the indoor air conditioner does not require frequent start, in order to achieve energy saving effect.

Preferably, a mounting structure for mounting the curtain wall system to the building, the mounting structure comprising a fixing base fixed to the building, a mounting frame connecting the adjacent inner glass curtain walls, and a connection mounting frame are further included The first corner code between the mount and the mount.

By adopting the above technical solution, the curtain wall system can be more conveniently installed on a building.

Preferably, the mounting frame comprises a first beam and a second beam for connecting to the building, a bead for holding the glass, and a frame connected to the outside of the bead, the first balance beam and the second balance beam Connected by profile.

By adopting the above technical solution, the first beam and the second beam are all installed around the building, and then the glass is mounted on the first beam and the second beam, and the inner side is not required to be the same as the existing installation method. After the structure of the glass curtain wall is completely installed, the outer glass curtain wall is installed, which is simpler and more convenient.

Preferably, the profile between the first beam and the second beam is provided with a ventilation grille.

By adopting the above technical solution, the ventilation grille is arranged such that the curtain wall systems between the layers communicate with each other.

Preferably, the middle portion of the bead is connected to the beam by a bolt, and the ends of the bead are recessed toward the inner side to form a card slot, and the inner ends of the two sides of the frame are convexly formed to form a block that fits with the card slot. .

By adopting the above technical solution, during the process of tightening the bead by bolts, the central portion may be excessively stressed, causing the two ends to lift up to lower the sealing performance of the hollow layer, increasing the heat loss of the hollow layer to improve energy consumption; When the outer frame can be excessively stressed in the middle of the bead, the two ends of the bead are effectively prevented from rising to improve the sealing performance, thereby reducing the loss of heat of the hollow layer.

Preferably, the temperature-sensing intelligent constant temperature ecological curtain wall system further comprises a fireproof sealing unit, and the fireproof sealing unit comprises a fireproof board sealed between the floor and the beam, and a fireproof rock wool fixed on the fireproof board.

By adopting the above technical solution, the building will use the chimney effect in the summer to reduce the temperature of the hollow layer, but in the event of a fire, the existence of the chimney effect is to aggravate the spread of fire, and the fireproof sealing unit is passed between the layers of the curtain wall. It can block the flame raft layer to achieve energy saving effect while improving safety performance.

Preferably, the fireproof sealing unit further comprises a pressure plate, and the fireproof rock wool is fixed on the fireproof board by a pressure plate.

By adopting the above technical solution, the setting of the pressure plate can improve the connection performance between the fireproof rock wool and the fireproof board, and improve the fireproof performance.

Preferably, the inner glass curtain wall is provided with a heat insulating structure on a side close to the indoor, and the heat insulating structure comprises a heat insulating aluminum plate, an insulating rock wool, and a locking member for fixing the heat insulating rock wool on the heat insulating aluminum plate. The insulated aluminum plate is fixed to the beam by the first corner code of the L-shape.

By adopting the above technical solution, the heat insulation structure is arranged on the inner glass curtain wall to further improve the heat insulation effect of the hollow layer, and the heat insulation aluminum plate has enhanced stability by connecting the beam with the L-shaped first corner code, and the heat insulation is strengthened by the locking member. The rock wool is pressed against the thermal insulation aluminum plate to prevent the surface of the thermal insulation aluminum plate from arching.

Preferably, the locking member comprises a fixing plate fixedly connected to the surface of the heat insulating aluminum plate, a locking rod fixed at one end of the fixing plate at one end and forming a hook portion through the thermal insulation rock wool, and sleeved at the hook portion for clamping Insulation rock wool locking plate.

By adopting the above technical solution, it is more convenient to fix the thermal insulation rock wool on the thermal insulation aluminum plate by this method.

Another object of the present invention is to provide a temperature control method which has the advantage of being more energy efficient.

The above technical object of the present invention is achieved by the following technical solutions: a temperature control method, which adopts the above intelligent constant temperature ecological curtain wall system,

Step one, through the hollow layer temperature sensor disposed on the inner glass curtain wall, detecting the temperature of the hollow layer and feeding back the temperature signal Tm in the hollow layer to the single chip microcomputer;

Step 2: The temperature signal Tm is received by the single-chip microcomputer and compared with the preset temperature Tx to control the temperature control unit to cool or heat to maintain the temperature of the hollow layer at the preset temperature Tx, wherein

When the temperature sensor of the hollow layer detects the temperature of the hollow layer and outputs the temperature signal Tm of the hollow layer, compared with the preset temperature Tx in the single chip microcomputer, when the temperature Tm of the hollow layer is lower than the preset temperature Tx, the single chip microcomputer controls the temperature control unit to perform heating. Until the hollow layer temperature Tm is equal to the preset temperature Tx, the heating operation is stopped, and only the airflow is exchanged;

In summary, the present invention has the following beneficial effects: the curtain wall is wrapped around the building, which is equivalent to wrapping a layer of insulation on the building, which can reduce the influence of the external environment on the indoor temperature, and can be used in winter. Effectively prevent the loss of indoor temperature, so that even if the indoor temperature can be maintained at a certain temperature for a long time, it is not necessary to start the indoor air conditioner frequently; in the summer, the presence of the thermal insulation layer can block the influence of the outdoor high temperature on the indoor low temperature, so that The indoor temperature can be maintained at a certain temperature for a long time, and it is not necessary to frequently start the indoor air conditioner to achieve the effect of energy saving; when the temperature control unit is controlled by the single chip microcomputer, the hollow layer can be made to be constant temperature and more energy-saving. The curtain wall system has also improved the fire protection unit to improve the fire safety performance while improving energy efficiency. The curtain wall system also improves the fireproof sealing unit, which improves the fire-saving safety performance while improving the energy-saving effect. The curtain wall system adopts an integrated curtain wall to make the installation more convenient and simpler.

DRAWINGS

1 is a schematic structural view of Embodiment 1;

2 is a circuit control diagram of an embodiment;

Figure 3 is an enlarged view of a portion A of Figure 1;

Fig. 4 is a view showing the connection relationship between the beam and the fireproof board in the first embodiment.

In the figure, 1, the inner glass curtain wall; 11, the vent; 2, the outer glass curtain wall; 3, the hollow layer; 4, the air conditioner; 52, the hollow layer temperature sensor; 71, the fixed seat; 721a, the first beam; 712b, the first Two beams; 7211, main body; 72111, first bump; 72112, stopper; 7212, cover plate; 72121, hook; 72122, curved groove; 722, bead; 7221, card slot; 723, outer frame; 7231, card block; 7232, second bump; 724, second corner code; 7241, first card slot; 73, first corner code; 74, column; Sealing unit; 81, fireproof board; 811, first recess; 812, second protrusion; 82, fire rock wool; 91, thermal insulation aluminum plate; 92, thermal insulation rock wool; 93, locking member; 931, lock bar; 9311, hook portion; 932, locking plate; 933, fixing plate; 94, connecting plate; 101, first protrusion; 102, second recess; 107, wall; 108, ventilation grille; 109, pressure plate.

detailed description

The invention will be further described in detail below with reference to the accompanying drawings.

Embodiment 1: An integrated intelligent constant temperature ecological curtain wall system comprising a mechanical part and a circuit part; wherein the mechanical part is as shown in FIG. 1 and comprises a unitary module.

The unit module is integrally installed around the building through the installation structure. The unit module includes the inner glass curtain wall 1, the outer glass curtain wall 2, the inner glass curtain wall 1 is a single layer of glass, and the outer glass curtain wall 2 is double glazed, the inner glass curtain wall 1 A hollow layer 3 is formed between the outer glass curtain wall 2 and a temperature control unit is disposed in the hollow layer 3. In the embodiment, the temperature control unit selects the inverter air conditioner 4.

A hollow layer temperature sensor 52 is disposed on the inner glass curtain wall 1.

Referring to FIG. 2, the circuit part of the curtain wall system, the single-chip model is AT89C51, wherein the input end is coupled to the hollow layer temperature sensor 52, and the output end is coupled to the temperature control unit. The model of the hollow layer temperature sensor 52 is DS18B20.

The energy-saving principle of the present embodiment will be described below with reference to FIG. 1 and FIG. 2. When the building is renovated, the temperature-sensing intelligent constant temperature ecological curtain wall system is decorated around the building, and then the cooling mode or system is realized by the control of the single-chip microcomputer. The thermal mode is used to adjust the temperature of the hollow layer 3 to maintain the temperature of the hollow layer 3 at a certain temperature value, which is equivalent to putting a constant temperature insulation layer on the building to achieve energy saving; for example, in winter, on the one hand, a greenhouse effect is formed in the hollow layer 3. On the other hand, the power consumption of the heating can be reduced; on the other hand, the presence of the thermal insulation layer can effectively prevent the indoor temperature from being lost, so that even if the indoor temperature can be maintained at a certain temperature for a long time, it is not necessary to frequently start the indoor air conditioner 4 .

In the summer, on the one hand, the presence of a constant temperature insulation layer can block the influence of outdoor high temperature on the indoor low temperature, so that the indoor temperature can be maintained at a certain temperature for a long time, and it is not necessary to frequently activate the indoor air conditioner 4 to achieve the effect of energy saving; It is important that the outer glass curtain wall 2 is double-glazed, which can effectively reduce the solar radiation in the summer, effectively block the outdoor heat from entering the hollow layer 3, thereby reducing the cooling power consumption of the hollow layer 3, while the inner glass The arrangement of the single-layer glass also allows the heat in the hollow layer 3 to be transferred to the room without being transmitted outdoors to further reduce the cooling power consumption.

A temperature control method, using the curtain wall system in the first embodiment, step one, detecting the temperature of the hollow layer 3 through the hollow layer temperature sensor 52 disposed on the inner glass curtain wall 1 and feeding back the temperature signal in the hollow layer 3 to the single chip microcomputer Tm;

Step 2: receiving the temperature signal Tm by the single chip microcomputer and comparing with the preset temperature Tx to control the temperature control unit to cool or Heating causes the temperature of the hollow layer 3 to be maintained at a preset temperature Tx, wherein

When the temperature of the hollow layer 3 is detected by the hollow layer temperature sensor 52, and the temperature signal Tm of the hollow layer 3 is output, compared with the preset temperature Tx in the single chip microcomputer, when the temperature Tm of the hollow layer 3 is lower than the preset temperature Tx, the temperature control of the single chip microcomputer is controlled. The unit performs heating until the temperature Tm of the hollow layer 3 is equal to the preset temperature Tx, the heating operation is stopped, and only the airflow is exchanged;

When the temperature of the hollow layer 3 is detected by the hollow layer temperature sensor 52, and the temperature signal Tm of the hollow layer 3 is output, compared with the preset temperature Tx in the single chip microcomputer, when the temperature Tm of the hollow layer 3 is higher than the preset temperature Tx, the temperature control of the single chip microcomputer is controlled. The unit performs cooling until the temperature Tm of the hollow layer 3 is equal to the preset temperature Tx, and the heating operation is stopped; the cycle is repeated to ensure that the temperature of the hollow layer 3 is at the preset temperature Tx. The preset temperature Tx in this embodiment is 22 degrees Celsius.

The mounting structure is described below with reference to FIG. 1, FIG. 3 and FIG. 4. The fixing seat 71 is embedded in the building wall 107, and the column 74 is mounted on the fixing base 71 through the first corner 73, and then the first beam 721a is attached. And the second beam 721b is mounted on the column 74 by a second corner 724.

The upper and lower adjacent inner glass curtain wall 1 and the outer glass curtain wall 2 are fixed by the action of the first beam 721a, the second beam 721b and the bead 722; the left and right adjacent inner glass curtain wall 1 and the outer glass curtain wall 2 pass through the column 74. The fixing is performed together with the action of the bead 722, and the ventilation grille 108 is provided on the profile connecting the first beam 721a and the second beam 721b.

It should be noted that the structure of the second beam 721b is the same as that of the first beam 721a. Referring to FIG. 4, the specific structure of the first beam 721a is as follows. The first beam 721a includes a main body 7211, and the top of the main body 7211 is open to form an opening. The opening protrudes inwardly to form a stopper 72112, and the opening cover is covered with a cover 7212. The cover 7212 has a hook 72121 on one side and an arcuate groove 72122 on the other side.

The first inner side wall of the main body 7211 is provided with a first protrusion 72111 along the longitudinal direction, and the second corner 724 is provided with a first card slot 7241 which is engaged with the first protrusion 72111.

1 and 4, the first beam 721a is divided into two parts, and all the columns 74 can be first installed on the outer wall of the building, and then the first beam 721a and the second beam 721b are installed, wherein A beam 721a and a second beam 721b are connected by a profile, so that the first and

second beams

721a, 721b can be simultaneously mounted on the building, and the main body 7211 is pre-installed when the first beam 721a and the second beam 721b are installed. The second corner code 724 is fixed into the main body 7211 through the opening, so that the second corner code 724 is relatively fixed in the vertical direction by the first protrusion 72111 and the first card slot 7241. The second corner code 724 is then fixed to the upright 74 by bolts, and the arcuate groove 72122 of the cover 7212 is placed in one of the stops 72112 and then engaged with the other stop 72112 by the hook 72121. This design eliminates the need for a column 74 and a beam to be installed, which can improve the installation efficiency of the curtain wall, and is equivalent to the beam to be used for installing the inner glass curtain wall 1 and for installing the outer glass. The beams of the curtain wall 2 are also all installed at the same time. It is not necessary to first install the inner glass curtain wall 1 and then repeat the original steps to install the outer glass curtain wall 2, which is more convenient and quick.

The central portion of the main body 7211 is convexly formed to form a connecting block, and the pressing strip 722 is fixed to the connecting block by bolts. The ends of the pressing strips 722 are recessed toward the inner side to form a latching slot 7221, and the bead 722 is provided with an outer frame 723 and two outer frames 723. The inner end of the side faces inwardly to form a block 7231 that cooperates with the card slot 7221.

When the bead 722 is tightened by bolts, the middle portion of the bead 722 is excessively stressed to cause the both ends to be lifted. When the two ends of the bead 722 are caught on the outer frame 723, the ends of the bead 722 can be effectively prevented from being excessively stressed in the middle of the bead 722. Lifting to improve the sealing performance, thereby reducing the loss of heat of the hollow layer 3. In addition, in order to further prevent the two ends of the bead 722 from being lifted up, a second protrusion 7232 may be disposed on the outer frame 723. When the outer frame 723 is covered on the bead 722, the second protrusion 7232 abuts against the end of the bead 722.

In order to enhance the sealing performance of the hollow layer 3, a sealing strip is provided on the end faces of the main body 7211 and the bead 722 in contact with the glass.

Referring to FIGS. 3 and 4, the fireproof repair unit 8 will be specifically described below; the fireproof repair unit 8 includes a fireproof board whose one side is connected to the wall 107 by bolts and is sealed between the floor and the beam 721 on the other side. 81. The fireproof rock wool 82 fixed on the fireproof board 81; the lower surface of the fireproof board 81 is provided with a first recess 811 formed by punching, and the upper surface of the outer frame 723 is provided with a first protrusion 101 matched with the first recess 811 The lower surface of the fireproof panel 81 further forms a second protrusion 812, and the upper surface of the outer frame 723 is formed with a second recess 102 that cooperates with the second protrusion 812; this design is similar to the relationship between the fireproof board 81 and the beam 721 The labyrinth seal is used, and when a fire occurs, heat is transferred to the inside of the beam 721, so that the air inside the outer frame 723 is thermally expanded, so that the outer frame 723 is deformed outward and protrudes outward, and the first protrusion is made at this time. The 101 is more firmly embedded in the first recess 811, and the second protrusion 812 is also better embedded in the second recess 102 to solve the sealing problem caused by the deformation of the outer frame 723, thereby improving the fireproofness of the curtain wall. performance. Referring to FIG. 3, a heat insulating structure is disposed on a side of the inner glass curtain wall 1 adjacent to the wall 107. The heat insulating structure includes an insulating aluminum plate 91 connected to the beam 721 through an L-shaped connecting plate 94, and the insulating aluminum plate 91 and the wall 107 are insulated. The thermal insulation rock wool 92 is filled between the thermal insulation rock wool 92 and the thermal insulation aluminum plate 91 is fixed by the locking member 93.

Referring to FIG. 3, the locking member 93 is specifically described as follows. It includes a fixing plate 933 fixedly attached to the surface of the heat insulating aluminum plate 91, a lock lever 931, and a curved locking plate 932. One end of the lock lever 931 is fixed to the fixing plate. The other end of the 933 passes through the insulating rock wool 92 to form a hook portion 9311.

In addition, in order to further improve the fireproof performance, a pressure plate 109 may be disposed on the fireproof rock wool 82, and the pressure plate 109 is fixed to the fireproof plate 81 by a locking member, wherein the structure of the locking member is the same as that of the locking member.

The specific embodiments are merely illustrative of the invention, which are not limiting of the invention, and those skilled in the art Modifications to the present embodiment that are not creatively made can be made as needed after reading this specification, but are protected by patent law as long as they are within the scope of the claims of the present invention.

Claims

An integrated intelligent constant temperature ecological curtain wall system, comprising an integrated unit module, the unit module is installed on the outer wall of the building, and the unit module comprises an inner glass curtain wall (1) and an outer glass curtain wall (2). A hollow layer (3) is formed between the inner glass curtain wall (1) and the outer glass curtain wall (2), wherein the inner glass curtain wall (1) is a single-layer glass, and the outer glass curtain wall (2) is The double-layer glass, the temperature-sensing intelligent constant temperature ecological curtain wall system further comprises a single-chip microcomputer, wherein the single-chip microcomputer is coupled with:

a hollow layer temperature sensor (52), disposed in the hollow layer (3) for detecting the temperature of the hollow layer (3) and outputting a temperature signal Tm;

The temperature control unit is disposed on the curtain wall mounting structure in the hollow layer (3), and is controlled by the single-chip microcomputer to realize a cooling mode or a heating mode to adjust the temperature of the hollow layer (3) to maintain the temperature of the hollow layer (3) at Presetting the temperature signal Tx, the solution comprises: when the hollow layer temperature sensor (52) detects the temperature of the hollow layer (3), and outputs the hollow layer (3) temperature signal Tm, compared with the preset temperature Tx in the single chip, wherein When the empty layer (3) temperature Tm is lower than the preset temperature Tx, the single-chip microcomputer controls the temperature control unit to perform heating until the temperature of the hollow layer (3) is equal to the preset temperature Tx, and the heating operation is stopped, and only the airflow is exchanged;

When the hollow layer temperature sensor (52) detects the temperature of the hollow layer (3) and outputs the temperature signal Tm of the hollow layer (3), compared with the preset temperature Tx in the single chip microcomputer, when the temperature Tm of the hollow layer (3) is higher than the preset At the temperature Tx, the single-chip microcomputer controls the temperature control unit to perform cooling until the hollow layer (3) temperature Tm is equal to the preset temperature Tx, and the heating operation is stopped; the cycle is repeated to ensure that the temperature of the hollow layer (3) is at the preset temperature Tx.
The integrated intelligent constant temperature ecological curtain wall system according to claim 1, further comprising: a mounting structure for mounting the unitary module to the building, the mounting structure comprising a fixing base fixed to the building. (71), connecting the mounting frame between the adjacent inner glass curtain walls (1) and connecting the first corner code (73) between the mounting frame and the fixing base (71).
The integrated intelligent constant temperature ecological curtain wall system according to claim 2, wherein said mounting frame comprises a first beam (721a) and a second beam (721b) for connection with the building, for clamping The bead (720) of the glass and the outer frame (723) attached to the outside of the bead (722), the first balance beam (721a) and the second balance beam (721b) are connected by a profile.
The integrated intelligent constant temperature ecological curtain wall system according to claim 3, wherein the profile between the first beam (721a) and the second beam (721b) is provided with a ventilation grille (108).
The integrated intelligent constant temperature ecological curtain wall system according to claim 4, wherein the middle portion of the bead (722) is connected to the beam (721) by bolts, and the ends of the bead (722) are recessed toward the inner side. The card slot (7221), the inner end of the two sides of the outer frame (723) protrudes inwardly to form a block (7231) that cooperates with the card slot (7221).
The integrated intelligent constant temperature ecological curtain wall system according to claim 3, wherein the integrated intelligent constant temperature ecological curtain wall system further comprises a fireproof sealing unit (8), wherein the fireproof sealing unit comprises a sealed connection on the floor and A fire board (81) between the beams (721) and a fire rock wool (82) fixed to the fire board (81).
The integrated intelligent constant temperature ecological curtain wall system according to claim 6, wherein the fireproof sealing unit further comprises a pressing plate (83), and the fireproof rock wool (82) is fixed to the fireproofing by a pressing plate (83). On the board (81).
The integrated intelligent constant temperature ecological curtain wall system according to claim 3, wherein: the inner glass curtain wall (1) is provided with a heat insulating structure on a side close to the indoor, and the heat insulating structure comprises a heat insulating aluminum plate (91). Insulating rock wool (92) and a locking member (93) for fixing the thermal rock wool (92) on the thermal insulating aluminum plate (91), the insulating aluminum plate (91) passing through the L-shaped connecting plate (94) A corner code (73) is fixed to the beam (721).
The integrated intelligent constant temperature ecological curtain wall system according to claim 8, wherein the locking member (93) comprises a fixing plate (933) fixedly connected to the surface of the thermal insulation aluminum plate (91), and one end is fixed and fixed. The other end of the plate (933) passes through the insulating rock wool (92) to form a lock lever (931) of the hook portion (9311) and a locking plate (931) that is sleeved on the hook portion (9311) for clamping the thermal insulation rock wool (92) ( 932).
A temperature control method using the integrated intelligent constant temperature ecological curtain wall system according to any one of claims 1 to 9;

Step 1, through the hollow layer temperature sensor (52) disposed on the inner glass curtain wall (1), detecting the temperature of the hollow layer (3) and feeding back the temperature signal Tm in the hollow layer (3) to the single chip microcomputer;

Step 2: The temperature signal Tm is received by the single-chip microcomputer and compared with the preset temperature Tx to control the cooling or heating of the temperature control unit to maintain the temperature of the hollow layer (3) at a preset temperature Tx, wherein

When the hollow layer temperature sensor (52) detects the temperature of the hollow layer (3) and outputs the temperature signal Tm of the hollow layer (3), compared with the preset temperature Tx in the single chip microcomputer, when the temperature Tm of the hollow layer (3) is lower than the preset At the temperature Tx, the single-chip microcomputer controls the temperature control unit to perform heating until the temperature of the hollow layer (3) is equal to the preset temperature Tx, and the heating operation is stopped, and only the airflow is exchanged;

When the hollow layer temperature sensor (52) detects the temperature of the hollow layer (3) and outputs the temperature signal Tm of the hollow layer (3), compared with the preset temperature Tx in the single chip microcomputer, when the temperature Tm of the hollow layer (3) is higher than the preset At the temperature Tx, the single-chip microcomputer controls the temperature control unit to perform cooling until the hollow layer (3) temperature Tm is equal to the preset temperature Tx, and the heating operation is stopped; the cycle is repeated to ensure that the temperature of the hollow layer (3) is at the preset temperature Tx.