TW201623771A - Intelligent window - Google Patents

Abstract

The invention discloses an intelligent window comprising a window, an airflow supplying module, a temperature sensing module, a control module and a window opening/closing module. The window is mounted in a wall body of a building. One end of the airflow supplying module covers a half of the window while the other end of the airflow supplying module is disposed in the wall body. The temperature sensing module includes an indoor temperature detecting unit and an outdoor temperature detecting unit. The indoor temperature detecting unit is mounted on a surface of the window and coupled to the control module, and the indoor temperature detecting unit is served to detect the temperature inside the building to generate an indoor temperature signal. The outdoor temperature detecting unit is embedded on another surface of the window and coupled to the control module, and the outdoor temperature detecting unit is served to detect the temperature outside the building to generate an outdoor temperature signal. The control module is coupled to the airflow supplying module, the indoor temperature detecting unit and the outdoor temperature detecting unit. The control module receives the indoor temperature signal and the outdoor temperature signal, and when the outdoor temperature signal is determined to be greater than the indoor temperature signal, the control module controls the end of the airflow supplying module to generate an exhausting vortex to exhaust air inside the building to the outside. The window opening/closing module is disposed at another side of the window and connected to a leaf body of the window and coupled to the control module. The window opening/closing module controls the leaf body to perform a displacement motion for opening or closing the window.

Description

Wisdom window

The present invention relates to a smart window, and more particularly to a smart window having a cyclone that can take indoor air out of the room or bring outdoor air into the room.

According to the general large-scale factory or warehouse, due to the large space and a large number of equipment or items, plus the hot air that may be emitted during the operation, although there are windows, it is still easy to have high temperature and cause sultry heat, in order to improve The comfort of the staff in the factory building or warehouse, in addition to the windows to enhance the air convection, there are also exhaust fans to force the hot air in the space to be pumped out, to enhance the air convection effect of the plant or warehouse, to reduce The purpose of reducing the space temperature.

The structure of the conventional exhaust fan is mainly disposed in a window, and the structure is provided with a casing for assembling a fan body and a motor, and the casing is mainly provided with a rectangular end portion and an exposed surface installed in the room. The outdoor end and the round outdoor front end are installed on the wall through the venting opening of the casing, so that the motor can drive the fan to operate, and the indoor hot air is sucked out to the outside, or the outdoor low temperature The air is drawn into the room to adjust the temperature of the room.

However, the conventional exhaust fan is not aesthetically pleasing, and it also affects the amount of light that the sun emits into the room. Moreover, for the average family, set the exhaust The fan will also obscure the beautiful scenery outside the window and lose the essence of the window.

As described above, the inventors of the present invention have thought about and designed a smart window in order to improve the lack of the prior art, thereby enhancing the implementation and utilization of the industry.

In view of the above-described problems of the prior art, it is an object of the present invention to provide a smart window to address the deficiencies of the prior art.

According to the purpose of the present invention, a smart window is provided, which comprises a window, an air supply module, a temperature sensing module, a control module and an opening and closing window module. The window is embedded in the wall of the building. One end of the air supply module covers one half of the window, and the other end of the air supply module is disposed on the wall. The temperature sensing module comprises an indoor temperature detecting unit and an outdoor temperature detecting unit. The indoor temperature detecting unit is embedded in one side of the window and coupled to the control module, and the indoor detecting unit senses the temperature inside the building to generate Indoor temperature signal. The outdoor temperature detecting unit is embedded on the other side of the window and coupled to the control module. The outdoor temperature detecting unit senses the temperature outside the building to generate an outdoor temperature signal. The control module is coupled to the air supply module and the temperature sensing module. When the control module receives the outdoor temperature signal and the indoor temperature signal, and determines that the outdoor temperature signal is greater than the indoor temperature signal, the control module controls the air supply module. An exhaust cyclone is generated at the end to allow the gas inside the building to exit the exterior of the building. The opening and closing window module is located on one side of the window, and the opening and closing window module is connected to the fan body of the window and coupled to the control module. The opening and closing window module controls the fan body to perform displacement operation to open or close the window.

Wherein, the control module determines that the outdoor temperature signal is less than the indoor temperature At the time of the signal, the control module controls the end of the air supply module to generate an intake cyclone to draw gas outside the building into the interior of the building.

The airflow supply module includes an airflow generation unit, an airflow control unit, an exhaust output unit, and a suction output unit. The airflow generating unit is disposed on the wall, the airflow generating unit body has a plurality of through holes, and the motor has a motor inside, and the motor sucks the gas outside the airflow generating unit through the plurality of through holes to generate the airflow. The airflow control unit is coupled to the control module, and one end of the airflow control unit is connected to the airflow generating unit, and the airflow control unit extends from the center opposite to the outside to form an exhaust gas delivery pipe and an air suction conveying pipe, and the airflow control unit receives the airflow. And selectively controlling the flow of air to the exhaust or suction delivery tube. The exhaust output unit is a hollow structure of the frame, and has an exhaust delivery port at the inner frame, the exhaust output unit covers half of one side of the window, and is connected to the exhaust delivery pipe, and the exhaust output unit receives the air flow, and the exhaust output The unit then produces an exhaust cyclone via the exhaust delivery port. The suction output unit is a hollow structure of the frame, and the inner frame has a suction delivery port, the suction output unit covers the other half of the window, and is connected to the suction delivery pipe, and when the suction output unit receives the air flow, the suction output unit is inhaled. The delivery port produces an inhalation cyclone.

Wherein, when the control module determines that the outdoor temperature signal is greater than the indoor temperature signal, the control module drives the airflow control unit to control the airflow to be sent to the exhaust delivery pipe, so that the exhaust output unit generates the exhaust cyclone through the exhaust delivery port, thereby The gas inside the object is discharged outside the building.

Wherein, when the control module determines that the outdoor temperature signal is smaller than the indoor temperature signal, the control module drives the airflow control unit to control the airflow to be delivered to the air suction conveying pipe, so that the suction output unit generates the suction cyclone through the suction conveying port, thereby making the building exterior The gas is drawn into the interior of the building.

The control module can be coupled to an external electronic device. When the control module receives the inhalation signal transmitted by the external electronic device, the control module controls the end of the airflow supply module to generate an inhalation cyclone.

The control module can be coupled to the external air-conditioning device. When the control module receives the execution signal transmitted by the external air-conditioning device, the control module drives the opening and closing window module to control the fan body to perform displacement to close the window.

Wherein, when the control module receives the stop signal transmitted by the external air-conditioning device, the control module drives the opening and closing window module to control the fan body to perform displacement actuation to open the window.

The control module can be coupled to an external electronic device. When the control module receives the open signal transmitted by the external electronic device, the control module drives the open/close window module to control the fan body to perform displacement to open the window.

The control module can be coupled to an external electronic device. When the control module receives the shutdown signal transmitted by the external electronic device, the control module drives the opening and closing window module to control the fan body to perform displacement to close the window.

In view of the above, the smart window of the present invention may have one or more of the following advantages:

(1) The smart window can be installed by the air supply module to generate an exhaust cyclone or a suction cyclone, and take indoor air out of the room or bring the outdoor air into the room, thereby eliminating the need for a fan. To achieve the effect of regulating indoor temperature and ventilation.

(2) The smart window can be connected to the external air-conditioning device by using the open/close window module according to the opening or closing of the external air-conditioning device. The fan body is selectively controlled for displacement actuation to open or close the window, thereby facilitating the automatic opening or closing of the window.

1‧‧‧Wisdom windows

10‧‧‧ windows

100‧‧‧ sector

11‧‧‧Airflow supply module

110‧‧‧Exhaust cyclone

111‧‧‧Inhalation cyclone

112‧‧‧Airflow generating unit

1120‧‧‧through hole

1121‧‧‧Motor

113‧‧‧Airflow control unit

1130‧‧‧Exhaust duct

1131‧‧‧Inhalation duct

114‧‧‧Exhaust output unit

1140‧‧‧Exhaust port

115‧‧‧Inhalation output unit

1150‧‧‧Inhalation port

12‧‧‧Temperature Sensing Module

120‧‧‧Indoor temperature detection unit

121‧‧‧Outdoor temperature detection unit

122‧‧‧Outdoor temperature signal

123‧‧‧Indoor temperature signal

13‧‧‧Control Module

14‧‧‧Open and close window module

2‧‧‧ wall

3‧‧‧External air-conditioning unit

30‧‧‧Execution signal

31‧‧‧ stop signal

4‧‧‧External electronic devices

40‧‧‧Close signal

41‧‧‧Open signal

42‧‧‧Exhaust signal

43‧‧‧Inhalation signal

5‧‧‧External transmission device

Figure 1 is a first schematic view of a first embodiment of a smart window of the present invention.

Figure 2 is a block diagram of a first embodiment of the smart window of the present invention.

Figure 3 is a second schematic view of a first embodiment of the smart window of the present invention.

Figure 4 is a schematic view of a second embodiment of the smart window of the present invention.

Figure 5 is a block diagram of a third embodiment of the smart window of the present invention.

Figure 6 is a block diagram of a fourth embodiment of the smart window of the present invention.

The technical features, contents, and advantages of the present invention, as well as the advantages thereof, can be understood by the present inventors, and the present invention will be described in detail with reference to the accompanying drawings. The subject matter is only for the purpose of illustration and supplementary description, and is not necessarily the true proportion and precise configuration after the implementation of the present invention. Therefore, the present invention should not be limited to the proportion and configuration relationship of the attached drawings. The scope of patents in actual implementation is described in advance.

The embodiments of the smart window according to the present invention will be described below with reference to the related drawings. For the sake of understanding, the same components in the following embodiments are denoted by the same reference numerals.

Please refer to FIG. 1 to FIG. 3 , which are respectively a first schematic diagram, a block diagram and a second schematic diagram of a first embodiment of the smart window of the present invention. As shown, the smart window 1 includes a window 10, an airflow supply module 11, a temperature sensing module 12, a control module 13, and an opening and closing window module. The window 10 is embedded in the wall 2 of the building. One end of the air supply module 11 covers one half of the window 10, and the other end of the air supply module 11 is disposed on the wall 2. The temperature sensing module 12 includes an indoor temperature detecting unit 120 and an outdoor temperature detecting unit 121. The indoor temperature detecting unit 120 is embedded in one side of the window 10 and coupled to the control module 13. The indoor temperature detecting unit 120 senses The temperature inside the building to generate an indoor temperature signal 122. The outdoor temperature detecting unit 121 is embedded on the other side of the window 10 and coupled to the control module 13. The outdoor temperature detecting unit 121 senses the temperature outside the building to generate the outdoor temperature signal 123. The control module 13 is coupled to the airflow supply module 11 and the temperature sensing module 12. The control module 13 receives the indoor temperature signal 122 and the outdoor temperature signal 123, and determines that the outdoor temperature signal 123 is greater than the indoor temperature signal 122. 13 then controlling the end of the airflow supply module 11 to generate an exhaust cyclone 110 to allow the gas inside the building to exit the exterior of the building. The opening and closing window module 14 is located on one side of the window 10. The opening and closing window module 14 is connected to the fan body 100 of the window 10, and is coupled to the control module 13. The opening and closing window module 14 controls the fan body to perform displacement actuation to open Or close the window 10.

Further, when the control module 13 determines that the outdoor temperature signal 123 is smaller than the indoor temperature signal 122, the control module 13 controls the airflow supply module 11 This end produces an intake cyclone 111 to draw gas outside the building into the interior of the building.

Specifically, the smart window 1 of the present invention can take the air supply module 11 to generate an exhaust cyclone or a suction cyclone, and take indoor air out of the room or bring the outdoor air into the room. The regulation of indoor temperature and ventilation can be achieved without setting a fan. At the same time, the smart window 1 of the present invention is also provided with a temperature sensing module 12 for sensing the temperature of the indoor and outdoor, and matching the foregoing modules to achieve automatic control of indoor temperature and ventilation. Therefore, the smart window 1 of the present invention can first sense the temperature inside and outside the building by the temperature sensing module 12, and the temperature sensing module 12 can be disposed on the window 10, but not limited thereto. . The temperature sensing module 12 preferably includes an indoor temperature detecting unit 120 and an outdoor temperature detecting unit 121. The indoor temperature detecting unit 120 is embedded in the window 10 facing one of the interiors of the building for sensing the temperature inside the building (ie, indoors) and correspondingly generating the indoor temperature signal 122. The outdoor temperature detecting unit 121 is embedded in the other side of the window 10 facing the exterior of the building for sensing the temperature outside the building (ie, outdoors) and correspondingly generating the outdoor temperature signal 123. After the indoor temperature detecting unit 120 and the outdoor temperature detecting unit 121 respectively sense and generate the outdoor temperature signal 123 and the indoor temperature signal 122, they are transmitted to the control module 13.

Next, the control module 13 performs a discrimination process. When the control module 13 determines that the outdoor temperature signal 123 is greater than the indoor temperature signal 122, it indicates that the outdoor temperature is higher than the indoor temperature. Therefore, the control module 13 supplies the module 11 to generate the exhaust cyclone 110 and discharges it to the outside. While the exhaust cyclone 110 is exhausted to the outside, the exhaust cyclone 110 also drives the gas inside the building to flow together, and the exhaust cyclone 110 is discharged to the outside of the building, thereby preventing the outdoor hot air from being poured into the room.

Conversely, when the control module 13 determines that the outdoor temperature signal 123 is smaller than the indoor temperature signal 122, it indicates that the outdoor temperature is lower than the indoor temperature, and the indoor system is at a higher temperature state. Therefore, the control module 13 controls the airflow supply module 11 An intake cyclone 111 is generated and blown into the room. While the suction cyclone 111 is blown into the room, the suction cyclone 111 also causes the gas outside the building to flow together, and blows the suction cyclone 111 toward the interior of the building, thereby lowering the temperature in the room. Moreover, the control module 13 can also drive the opening and closing window module 14 to control the displacement of the fan body 100 to open or close the window 10.

Thereby, the smart window 1 of the invention can automatically adjust the indoor temperature and ventilation effect without setting a fan.

Please refer to FIG. 4, which is a schematic diagram of a second embodiment of the smart window of the present invention, and please refer to FIG. 1 to FIG. 3 together. As shown in the figure, the smart window in this embodiment is similar to the operation of the same components described in the smart window of the first embodiment, and therefore will not be described herein. However, it is worth mentioning that in the present embodiment, the airflow supply module 11 includes an airflow generation unit 112, an airflow control unit 113, an exhaust gas output unit 114, and a suction output unit 115. The airflow generating unit 112 is disposed on the wall 2. The airflow generating unit 112 has a plurality of through holes 1120, and has a motor 1121 therein. The motor 1121 absorbs gas outside the airflow generating unit 112 by using a plurality of through holes 1120 to generate an airflow. The airflow control unit 113 is coupled to the control module 13. One end of the airflow control unit 113 is connected to the airflow generating unit 112, and the airflow regulating unit 113 extends from the center opposite to the outside to form an exhaust gas delivery pipe 1130 and an air suction pipe 1131. The airflow control unit 113 receives the airflow and selectively controls the airflow to be delivered to the exhaust delivery pipe 1130 or the suction delivery pipe 1131. The exhaust gas output unit 114 is a frame hollow structure, and has an exhaust gas delivery port 1140 at the inner frame, and the exhaust gas output unit 114 covers When the exhaust gas delivery pipe 1130 is connected to the half of one side of the window 10 and the exhaust gas output unit 114 receives the air flow, the exhaust gas output unit 114 generates the discharge cyclone 110 via the exhaust gas delivery port 1140. The suction output unit 115 is a frame hollow structure, and has a suction delivery port 1150 at the inner frame, the suction output unit 115 covers the other half of the window 10, and is connected to the suction delivery pipe 1131, and the suction output unit 115 receives the air flow. The suction output unit 115 generates the suction cyclone 111 via the suction delivery port 1150.

In detail, the airflow supply module 11 of the present invention includes an airflow generation unit 112, an airflow control unit 113, an exhaust gas output unit 114, and a suction output unit 115. The exhaust gas output unit 114 and the suction output unit 115 are both hollow structures of the frame, respectively covering the front and rear sides of the window 10 and occupying half of the window 10, and the exhaust gas output unit 114 and the inner frame of the suction output unit 115 respectively have exhaust gas transportation. The port 1140 and the suction port 1150 are respectively used to generate the exhaust cyclone 110 and the suction cyclone 111.

The airflow generating unit 112 is disposed on the wall 2, and is connected to the exhaust output unit 114 and the suction output unit 115 via the airflow adjusting unit 113. The airflow generating unit 112 may be a hollow housing structure having a plurality of through holes 1120 in the body thereof, and The internal airflow generating unit 112 has a motor 1121 that can draw outside air through a plurality of through holes 1120 and generate an airflow. One end of the airflow control unit 113 is connected to the airflow generating unit 112, and the other end of the airflow regulating unit 11 extends from the end opposite to the center of the airflow regulating unit 11 to form an exhaust gas conveying pipe 1130 and an air suction conveying pipe 1131, and the exhaust gas conveying pipe 1130. The exhaust gas output unit 114 is connected, and the intake gas delivery pipe 1131 is connected to the suction output unit 115.

After the airflow generating unit 112 generates the airflow, the airflow adjusting unit 113 can selectively control the airflow to the exhaust according to the driving of the control module 13. The delivery tube 1130 is delivered to the inspiratory delivery tube 1131.

Further, when the control module 13 determines that the outdoor temperature signal 123 is greater than the indoor temperature signal 122, the control module 13 drives the airflow control unit 113 to control the airflow to the exhaust delivery pipe 1130, so that the exhaust gas output unit 114 is delivered via the exhaust gas. The port 1140 produces an exhaust cyclone 110 which in turn allows the gas inside the building to exit the exterior of the building.

On the contrary, when the control module 13 determines that the outdoor temperature signal 123 is smaller than the indoor temperature signal 122, the control module 13 drives the airflow control unit 113 to control the airflow to the intake delivery pipe 1131 so that the suction output unit 115 passes through the suction delivery port 1150. An intake cyclone 111 is generated to inhale gas outside the building into the interior of the building.

That is, when the control module 13 determines that the outdoor temperature signal 123 is greater than the indoor temperature signal 122, it is required to generate the exhaust cyclone 110 to the outside. Therefore, the control module 13 can drive the airflow control unit 113 to control the airflow to the exhaust delivery. The tube 1130 is transmitted to the exhaust gas output unit 114 via the exhaust gas delivery pipe 1130, so that the exhaust gas output unit 114 can generate the exhaust gas cyclone 110 by using the exhaust gas delivery port 1140, thereby causing the gas inside the building to exit the building with the exhaust gas cyclone 110. Outside the object, avoiding outdoor hot air pouring into the room.

When the control module 13 determines that the outdoor temperature signal 123 is smaller than the indoor temperature signal 122, the intake cyclone 111 needs to be generated and blown into the room. Therefore, the control module 13 can drive the airflow control unit 113 to control the airflow to the exhaust delivery pipe 1130, and transmit it to the intake delivery pipe 1131 via the exhaust delivery pipe 1130, so that the suction output unit 115 generates the suction through the suction delivery port 1150. a cyclone 111, which in turn causes the gas outside the building to blow into the building along with the suction cyclone 111 Department, while reducing the temperature inside the room.

Please refer to FIG. 5, which is a block diagram of a third embodiment of the smart window of the present invention, and please refer to FIG. 1 to FIG. 4 together. As shown in the figure, the smart window in this embodiment is similar to the operation of the same components described in the smart windows of the above embodiments, and thus will not be described herein. However, it is worth mentioning that the control module 13 can be coupled to the external air conditioner 3 (such as a domestic air conditioner). When the control module 13 receives the execution signal 30 transmitted by the external air conditioner 3, the control module 13 drives the activation module 13 The closed window module 14 controls the sector 100 to perform a displacement operation to close the window 10. Conversely, when the control module 10 receives the stop signal 31 transmitted by the external air conditioner 3, the control module 10 drives the opening and closing window module 14 to control the sector 100 to perform displacement operation to open the window 10.

In other words, the control module 13 can be coupled to the external air conditioner 3, and according to the execution signal 30 or the stop signal 31 (ie, the signal that the external air conditioner 3 operates or stops) transmitted by the external air conditioner 3, to drive the opening and closing window. The module 14 is actuated to control the displacement of the fan body 100 to achieve the effect of automatically opening or closing the window 10.

Please refer to FIG. 6 , which is a block diagram of a fourth embodiment of the smart window of the present invention, and please refer to FIG. 1 to FIG. 5 together. As shown in the figure, the smart window in this embodiment is similar to the operation of the same components described in the smart windows of the above embodiments, and thus will not be described herein. However, it is worth mentioning that, in this embodiment, the control module 13 can be coupled to the external electronic device 4. When the control module 13 receives the shutdown signal 40 transmitted by the external electronic device 4, the control module 13 The opening and closing window module 14 is driven to control the fan body 100 to perform a displacement operation to close the window 10. In contrast, the control module 13 can be coupled to the external electronic device 4, and the control module 13 can control when the open signal 41 transmitted by the external electronic device 4 is received. The module 13 is configured to drive the opening and closing window module 14 to control the movement of the fan body 100 to open the window 10.

Further, the control module 13 can be coupled to the external electronic device 4, and when the control module 13 receives the exhaust signal 42 transmitted by the external electronic device 4, the control module 13 controls the end of the airflow supply module 11 accordingly. The cyclone 110 is exhausted. In contrast, the control module 13 can be coupled to the external electronic device 4, and when the control module 13 receives the inhalation signal 43 transmitted by the external electronic device 4, the control module 13 controls the end of the airflow supply module 11 to generate inhalation. Cyclone 111.

In other words, the control module 13 of the present invention can be coupled to the external electronic device 4 (such as a smart phone, a desktop computer, or a notebook computer) by wireless or wired transmission, and transmitted according to the external electronic device 4. Various signals, such as turn-off signal 40, turn-on signal 41, exhaust signal 42 and inhalation signal 43, are actuated accordingly. That is, when the control module 13 receives the shutdown signal 40 transmitted by the external electronic device 4, the control module 13 drives the opening and closing window module 14 to control the movement of the sector 100 to close the window 10.

In addition, the control module 13 can be coupled to the external transmission device 5 to couple the external electronic device 4 via the external transmission device 5 and receive the signal transmitted by the external electronic device 4. That is, the control module 13 can be coupled to the external electronic device 4 through the external transmission device 5 (such as a network router) and receive the signal transmitted by the external electronic device 4.

The above is intended to be illustrative only and not limiting. Any equivalent modifications or alterations to the spirit and scope of the invention are intended to be included in the scope of the appended claims.

10‧‧‧ windows

11‧‧‧Airflow supply module

110‧‧‧Exhaust cyclone

111‧‧‧Inhalation cyclone

2‧‧‧ wall

Claims (10)

A smart window comprising: a window embedded in a wall of a building; an air supply module having one end covering a half of the window, the other end of the air supply module being disposed on the wall a temperature sensing module, comprising: an indoor temperature detecting unit embedded in one side of the window and coupled to the control module, the indoor detecting unit sensing the temperature inside the building, Generating an indoor temperature signal; and an outdoor temperature detecting unit embedded in the other side of the window and coupled to the control module, the outdoor temperature detecting unit sensing the temperature outside the building to generate an outdoor a temperature control signal, a control module coupled to the airflow supply module and the temperature sensing module, the control module receiving the outdoor temperature signal and the indoor temperature signal, and determining that the outdoor temperature signal is greater than the indoor temperature signal The control module controls the end of the air supply module to generate an exhaust cyclone to discharge the gas inside the building to the outside of the building; and an opening and closing window module located at the window Side, the window opening and closing the window module connected to a member of, and coupled to the control module, which controls the opening and closing window module a diversion of the movable body fan, to open or close the window. The smart window of claim 1, wherein the control module determines that the outdoor temperature signal is less than the indoor temperature signal, the control module controls the end of the air supply module to generate an inhalation Cyclone to draw gas outside the building into the interior of the building. The smart window of claim 2, wherein the airflow supply module comprises: an airflow generating unit disposed on the wall, the airflow generating unit body having a plurality of through holes, and a motor inside The motor extracts a gas outside the airflow generating unit by the plurality of through holes to generate a gas flow; a gas flow regulating unit coupled to the control module, the one end of the airflow regulating unit is connected to the airflow generating unit, and the motor The airflow control unit extends from the center opposite to the outside to form an exhaust duct and a suction duct, the airflow adjusting unit receives the airflow, and selectively controls the airflow to be sent to the exhaust duct or the An air suction delivery pipe; an exhaust gas output unit having a frame hollow structure, and an exhaust gas delivery port at the inner frame, the exhaust gas output unit covering a half of one side of the window and connecting the exhaust gas delivery pipe And when the exhaust gas output unit receives the airflow, the exhaust gas output unit generates the exhaust gas cyclone through the exhaust gas delivery port; and a suction output unit, which is in the frame An empty structure, and the inner frame has a suction delivery port covering the other half of the window and connecting the suction delivery tube, and the suction output unit receives the air flow, the suction output unit The suction cyclone is generated via the suction delivery port. The smart window of claim 3, wherein the control module determines that the outdoor temperature signal is greater than the indoor temperature signal, The control module drives the airflow control unit to control the airflow to be sent to the exhaust delivery pipe, so that the exhaust gas output unit generates the exhaust gas cyclone through the exhaust gas delivery port, thereby discharging the gas inside the building to the building. external. The smart window of claim 3, wherein the control module determines that the outdoor temperature signal is less than the indoor temperature signal, the control module drives the airflow control unit to control the airflow to the suction delivery tube. So that the suction output unit generates the suction cyclone through the suction delivery port, thereby allowing gas outside the building to be sucked into the interior of the building. The smart window of claim 2, wherein the control module is coupled to an external electronic device, and the control module receives an inhalation signal transmitted by the external electronic device, Controlling the end of the airflow supply module produces the suction cyclone. The smart window of claim 1, wherein the control module is coupled to an external air-conditioning device, and the control module drives the one of the execution signals transmitted by the external air-conditioning device. The closed window module controls the fan to perform the displacement to close the window. The smart window of claim 7, wherein the control module drives the open/close window module to control the fan body to perform the displacement when the control module receives a stop signal transmitted by the external air conditioner. Actuate to open the window. Such as the wisdom window described in claim 8 of the patent scope, wherein the control The module is coupled to an external electronic device. When the control module receives an opening signal transmitted by the external electronic device, the control module drives the opening and closing window module to control the fan body to perform the displacement operation. To open the window. The smart window of claim 1, wherein the control module is coupled to an external electronic device, and the control module receives a turn-off signal transmitted by the external electronic device, the control module The opening and closing window module is driven to control the fan body to perform the displacement operation to close the window.