CN216641858U - Intelligent window - Google Patents

Abstract

The utility model discloses an intelligent window, wherein the intelligent window comprises an automatic screen window, the automatic screen window comprises a screen window frame, at least one screen component and at least one screen driving device, the screen window frame is provided with an accommodating space, the screen component and the screen driving device are kept in the accommodating space, the screen driving component is connected with the screen driving device in a driving way, the screen driving device can drive the screen component to move relative to the screen window frame and allow the automatic screen to be switched between an unfolding state and an accommodating state, the intelligent window does not need to be pushed or pulled by a user, and the automation degree of the intelligent window is improved.

Description

Intelligent window

Technical Field

The utility model relates to the field of doors and windows, in particular to an intelligent window.

Background

The window is an indispensable part of buildings and houses, can be used for decorating the buildings and is also a main channel for communicating indoor and outdoor environments, determines the ventilation and lighting effects of the buildings, and has important influence on the indoor environment with comfortable structure.

Common windows comprise a horizontal sliding window, a reversed window and the like, and users can select and install different types of windows according to the characteristics and the use requirements of buildings so as to meet the requirements of indoor lighting and ventilation. However, the existing window is low in automation degree and intelligence, and still has a plurality of problems in the using process. Taking a sliding window as an example, the sliding window comprises a window frame, two sashes and a plurality of felt strips, wherein an upper window frame and a lower window frame of the window frame are respectively provided with two opposite sliding chutes, and two side window frames of the window frame are respectively provided with two opposite accommodating grooves. The two window sashes are installed in the sliding grooves of the upper window frame and the lower window frame in a staggered mode, and the window sashes can be driven to move in the sliding grooves, so that the horizontal drawing window can be switched between an opening state and a closing state. When at least one of the sashes leaves the accommodating groove of the side window frame, the horizontal sliding window is in the open state, and the indoor environment is communicated with the external environment. After the two window sashes are respectively kept in the containing grooves of the two side window frames, the felt strips arranged on the window sashes are attached to the side window frames, and the casement window is in the closed state and blocks the airflow exchange between the external environment and the indoor environment. The felt strips of the window sash can improve the sound insulation and sealing effects of the horizontal sliding window and reduce the influence of the external environment on the indoor environment. After the felt strips are attached to the side window frame, a user needs a large force to separate the window sash from the side window frame. Secondly, if the user is in rainy days or has large outdoor wind and sand, once the user does not close the sliding window in time, rainwater or wind and sand can enter the room to pollute the indoor environment or damage indoor furniture. Moreover, if the horizontal sliding window is in the closed state for a long time, the indoor ventilation condition becomes worse, the indoor air is turbid, and the comfort of the indoor environment is reduced.

In addition, most users can install a screen window on the inner side of the window sash, and after the window sash is opened, the screen window is closed, so that the indoor ventilation is guaranteed, and mosquitoes and flies are prevented from entering a room. The existing screen window is also completely opened and closed by a user, and once the user forgets to close the screen window, mosquitoes and flies can enter the room. In addition, the existing screen window and the existing window sash are of independent structures, and in order to ensure the normal sliding of the screen window and the window sash, a gap is reserved between the screen window and the window sash, so that the situation that the window sash blocks the sliding of the screen window or the screen window blocks the sliding of the window sash is avoided. The structure is not only poor in aesthetic property, but also easy to cause mosquitoes and flies to enter a room from a gap between the screen window and the window sash. Moreover, although the screen window is provided with a plurality of fine mesh holes to ensure the indoor light-passing effect and ventilation, the screen window may shield light entering the indoor after being installed at the inner side of the window sash. In addition, the existing screen window is exposed in the air for a long time, water vapor in the air covers the surface of the screen mesh, so that the screen mesh is easy to rust or even damage, the service life of the screen window is influenced, a user needs to replace the screen mesh of the screen window or replace the whole screen window to normally use, and the use cost and the maintenance cost of the screen window are improved.

SUMMERY OF THE UTILITY MODEL

An object of the present invention is to provide a smart window, wherein the smart window provides an automatic window that can automatically switch between an open state and a closed state without being pushed or pulled by a user, thereby improving the degree of automation of the smart window.

Another objective of the present invention is to provide an intelligent window, wherein the intelligent window provides an automatic screen window, wherein the automatic screen window can be automatically switched between an expanded state and a storage device, and the automatic screen window in the expanded state shields the automatic window and prevents outdoor mosquitoes and flies from entering the room, and a screen of the automatic screen window in the storage state can be hidden, so that not only is the volume of the automatic screen window reduced, but also the automatic screen window is prevented from shielding the automatic window to affect the light transmittance performance of the intelligent window.

Another object of the present invention is to provide an intelligent window, wherein the automatic screen window of the intelligent window can switch its own working state according to the working state of the automatic window, and when the automatic window is adjusted to the open state, the automatic screen window is switched to the expanded state; when the automatic window body is adjusted to the closed state, the automatic screen window is switched to the storage state, and the automatic window body and the automatic screen window are matched with each other to work, so that a more comfortable indoor environment is created, and the intelligence of the intelligent screen window is improved.

Another object of the present invention is to provide an intelligent window, wherein when the automatic screen window of the intelligent window is in the storage state, the screen mesh of the automatic screen window is hidden, so as to prevent the automatic screen window from being exposed to the air for a long time, which is beneficial to prolonging the service life of the automatic screen window and reducing the use cost and maintenance cost of the automatic screen window.

Another object of the present invention is to provide a smart window, wherein the automatic screen window and the automatic window are integrated, which is advantageous to improve the aesthetic appearance of the smart window.

Another object of the present invention is to provide a smart window, wherein the automatic window of the smart window can be intelligently switched between the open state and the closed state according to an environmental factor, which is beneficial to creating a more comfortable and healthy indoor environment.

Another object of the present invention is to provide a smart window, wherein the automatic window of the smart window can automatically switch between the open state and the closed state according to an operating state of an indoor air treatment device, which is beneficial to improve the operating efficiency of the air treatment device and save power consumption.

It is another object of the present invention to provide a smart window, wherein the smart window provides an air circulation device capable of switching its own operation state according to the operation state of the automatic window. For example, when the automatic window body is in the closed state, the air circulating device is in the working state, so that normal circulation and circulation of indoor and outdoor air are guaranteed, and the phenomenon that the air is dirty due to long-time sealing in the room is avoided.

Another object of the present invention is to provide a smart window, wherein the smart window provides a self-cleaning device, wherein the self-cleaning device can monitor the contaminants on the surface of the automatic window, and automatically clean the surface of the automatic window when the contaminants on the surface of the automatic window reach a cleaning warning value, so as to not only ensure the cleanliness and the aesthetic property of the automatic window, but also avoid the influence of excessive contaminants attached to the surface of the automatic window on the light transmittance of the automatic window.

According to one aspect of the present invention, there is provided a smart window, comprising:

an automatic screen window, wherein the automatic screen window comprises a screen window frame, at least one screen assembly and at least one screen driving device, wherein the screen assembly and the screen driving device are installed on the screen window frame, the screen driving device is connected with the screen driving device in a driving mode, and the screen driving device can drive the screen assembly to move relative to the screen window frame and allow the automatic screen window to be switched between an unfolding state and a storage state.

According to an embodiment of the present invention, the screen window frame has an accommodating space in which the screen assembly and the screen driving means are held.

According to an embodiment of the present invention, the smart window further comprises an automatic window, wherein the automatic screen is held at one side of the automatic window, the automatic screen is communicably connected to the automatic window, the automatic window is capable of automatically switching between an open state and a closed state, the automatic screen is automatically adjusted to the open state when the automatic window is in the open state, and the automatic screen is automatically adjusted to the storage state when the automatic window is in the closed state.

According to one embodiment of the utility model, the screen assembly comprises a receiving post and a screen, wherein the screen is movably wound around the receiving post in such a way that an inner end portion of the screen is fixed to the receiving post, and an outer end portion of the screen is connected to the screen driving device, and the screen driving device can drive the screen to move relative to the receiving post so as to allow the automatic window to be switched between the open state and the receiving state.

According to one embodiment of the present invention, the screen driving device includes a screen driving motor, a screen belt drivingly connected to the screen driving motor, and a screen holder attached to the belt, the screen being fixed to the screen holder.

According to one embodiment of the utility model, the receiving posts of the screen assembly are drivingly and rotationally connected to the screen drive motor.

According to one embodiment of the present invention, the screen of the screen active assembly is mounted to the receiving post by a flat spring.

According to an embodiment of the utility model, the automotive screen further comprises an active closure and a passive closure, wherein the active closure is provided to the screen, the passive closure is provided to the screen window frame, and the active closure of the automotive screen in the unfolded state is detachably attached to the passive closure.

According to an embodiment of the present invention, the screen assembly and the screen driving means of the automatic window screen are implemented as one, and the automatic window screen is of a one-piece structure.

According to an embodiment of the present invention, the automatic screen window further includes an active closing member and a passive closing member, the screen assemblies and the screen driving means of the automatic screen window are implemented in two, the automatic screen window is of a two-piece structure, the active closing member and the passive closing member are respectively provided to the screens of the two screen assemblies, and the active closing member of the automatic screen in the unfolded state is detachably attached to the passive closing member.

According to an embodiment of the present invention, the screen assembly further includes a protective case, wherein the protective case has a receiving space communicated with a side opening of the receiving space, wherein the screen is held in the receiving space of the protective case, and the screen may extend outward from the side opening.

According to an embodiment of the present invention, the automatic window comprises a window frame, at least one sash, and at least one sash driving device, wherein the window frame has an installation space, the sash driving device is installed in the installation space of the window frame, the sash is connected to the sash driving device in a manner of being movably installed in the window frame, and the sash driving device can drive the sash to move relative to the window frame so as to allow the automatic window to be switched between the open state and the closed state.

According to an embodiment of the present invention, the window sash driving device of the automatic window comprises a window sash driving motor, a window sash transmission belt, and a window sash fixing member, wherein the window sash transmission belt is drivably connected to the window sash driving motor, the window sash fixing member is installed at the window sash transmission belt, and the window sash is connected to the window sash fixing member.

According to an embodiment of the utility model said sash driving means of said automatic window and said screen driving means of said automatic window are implemented as electric pushers or hydraulic pushers.

According to an embodiment of the present invention, the smart window further comprises an environmental factor detection device, wherein the environmental factor detection device is communicably connected to the automatic window, and the automatic window automatically adjusts the operation state according to an environmental factor detected by the environmental factor detection device.

According to an embodiment of the utility model, the environmental factor detection means is selected from the group of types consisting of a temperature sensor, a humidity sensor, a dust sensor, a wind sensor and a rain sensor.

According to one embodiment of the present invention, the automatic window is communicatively connected to an air treatment device in a room, wherein the automatic window adjusts its operating state according to changes in the operating state of the air treatment device.

According to an embodiment of the present invention, the smart window further comprises a fresh air device, wherein the fresh air device is communicably connected to the automatic window and is automatically enabled after the automatic window is in the closed state.

According to an embodiment of the present invention, the smart window further comprises a self-cleaning device, wherein the self-cleaning device is mounted to an outer surface of the sash of the automatic window, the self-cleaning device automatically cleans the outer surface of the sash, and the self-cleaning device is communicatively connected to the automatic window, the automatic window being maintained in the closed state before the self-cleaning device cleans the outer surface of the sash.

According to an embodiment of the present invention, the self-cleaning device detects dirt on the surface of the window sash, when the dirt on the outer surface of the window sash reaches a cleaning alarm value, the automatic window is kept in the closed state, and the self-cleaning device automatically cleans the outer surface of the window sash.

According to an embodiment of the present invention, the smart window further comprises a control device, wherein the control device is communicably connected to the automatic window and the automatic screen, and the operation states of the automatic window and the automatic screen can be adjusted by operating the control device.

According to an embodiment of the present invention, the smart window further comprises a communication means, wherein the communication means is communicably connected to the automatic window, the automatic screen and the environmental factor detection means, the communication means allowing to be communicably connected to an electronic device.

According to an embodiment of the present invention, the smart window further comprises a storage device, wherein the storage device is communicably connected to the automatic window, the automatic screen window and the environmental factor detection device, and the storage device allows storage of a detection result of the environmental factor detection device and a change in operation state of the automatic window and the automatic screen window.

Drawings

Fig. 1 is a schematic block diagram of a smart window according to a preferred embodiment of the present invention.

Fig. 2 is an exploded view schematically illustrating the smart window according to the above preferred embodiment of the present invention.

Fig. 3 is an exploded view schematically illustrating a partial structure of the smart window according to the above preferred embodiment of the present invention, which illustrates an automatic window screen of the smart window in a storage state when an automatic window of the smart window is in a closed state.

Fig. 4 is an exploded view schematically illustrating a partial structure of the smart window according to the above preferred embodiment of the present invention, which illustrates that the automatic screen window is in an unfolded state when the automatic window of the smart window is in an opened state.

Fig. 5 is a schematic view illustrating an application of the smart window according to the above preferred embodiment of the present invention, which shows that the automatic window can automatically adjust an operation state according to the detection results of a humidity sensor and a temperature sensor.

Fig. 6 is a schematic view illustrating an application of the smart window according to the above preferred embodiment of the present invention, which shows that the automatic window can automatically adjust the operation state according to the detection results of a wind sensor and a dust sensor.

Fig. 7 is a schematic view illustrating an application of the smart window according to the above preferred embodiment of the present invention, which shows that the automatic window can automatically adjust an operation state according to the detection results of the rainfall sensor and the temperature sensor.

Fig. 8 is a schematic view illustrating an application of the smart window according to the above preferred embodiment of the present invention, which shows that the automatic window can automatically adjust an operation state according to a change in an operation state of an air treatment device in a room.

Fig. 9 is a schematic diagram of an application of the smart window according to the above preferred embodiment of the present invention, which shows that a fresh air device of the smart window is switched to an operation state in response to the automatic window when the automatic window is switched to a closed state.

Fig. 10 is a schematic view illustrating an application of the smart window according to the above preferred embodiment of the present invention, which shows a self-cleaning apparatus of the smart window in automatically cleaning the surface of the automatic window.

Fig. 11 is a schematic view illustrating an application of the smart window according to the above preferred embodiment of the present invention, which shows that the smart window is allowed to be remotely controlled.

Fig. 12 is a schematic block diagram of the smart window according to another preferred embodiment of the present invention.

Fig. 13 is a schematic structural diagram of the smart window according to the above preferred embodiment of the present invention.

Detailed Description

The following description is presented to disclose the utility model so as to enable any person skilled in the art to practice the utility model. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The underlying principles of the utility model, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the utility model.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced devices or components must be constructed and operated in a particular orientation and thus are not to be considered limiting.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

Referring to the accompanying drawings 1 to 11 of the specification, a smart window 100 according to the present invention will be described in the following description, wherein the smart window 100 includes an automatic window 10 and an automatic screen 20, wherein the automatic screen 20 is disposed at one side of the automatic window 10, the automatic window 10 can be automatically switched between an open state and a closed state, and the automatic screen 20 can be automatically switched between an open state and a storage state without being manually pushed or pulled by a user, thereby improving the degree of automation of the smart window 100.

Specifically, the automatic window 10 includes a window frame 11, at least one window sash 12, and at least one window sash driving device 13, wherein the window sash 12 is movably mounted on the window frame 11, the window sash 12 is drivably connected to the window sash driving device 13, and the window sash driving device 13 can drive the window sash 12 to move relative to the window frame 11, so that the automatic window 10 can be switched between the open state and the closed state.

It is worth mentioning that the automatic window 10 of the smart window 100 may be implemented as a sliding window, a reversing window or other types of windows known to the person skilled in the art. The number of the window sashes 12 may be implemented as one, two, three or more, and the embodiment of the automatic window 10 is only an example and cannot be a limitation on the content and scope of the smart window 100 of the present invention. In the following description, the automatic window 10 is implemented as a sliding window, and the automatic window 10 includes two sashes 12.

Referring to fig. 2, said window frame 11 of said automatic window 10 comprises an upper frame 111, a lower frame 112 opposite to said upper frame 11, a left frame 113 and a right frame 114 opposite to said left frame 113, said left frame 113 and said right frame 114 being held between said upper frame 111 and said lower frame 112, respectively. The two sashes 12 are slidably installed on the upper window frame 111 and the lower window frame 112 from left to right, and when the two sashes 12 are respectively attached to the left window frame 113 and the right window frame 113, the automatic window 10 is in the closed state, and the automatic window 10 can isolate indoor and outdoor spaces. When an opening is formed between the window sash 12 and the left window frame 113 and/or the right window frame 114, the automatic window 10 is in the open state, and the opening of the automatic window 10 communicates indoor and outdoor spaces.

Referring to fig. 2 to 11, in an embodiment of the present invention, the window sash driving device 13 includes a window sash driving motor 131, a window sash transmission belt 132, and a window sash fixing member 133, wherein the window sash transmission belt 132 is connected to the window sash driving motor 131 in a driving manner, the window sash fixing member 133 is mounted to the window sash transmission belt 132, and the window sash 12 is fixed to the window sash fixing member 133. The window sash driving motor 131 drives the window sash transmission belt 132 to move left and right, and drives the window sash 12 fixed to the window sash transmission belt 132 to move left and right, so that the automatic window 10 can be switched between the open state and the closed state.

Alternatively, the window sash driving device 13 is implemented as an electric push rod, and the window sash driving device 13 drives the window sash 12 to move relative to the window frame 11 in an electric telescopic manner. For example, the window sash 12 moves left and right relative to the window frame 11 following the extension and contraction of the electric push rod, thereby switching between the open state and the closed state. Optionally, the window sash driving device 13 is implemented as a hydraulic push rod, and the window sash driving device 13 drives the window sash 12 to move relative to the window frame 11 in a hydraulic telescopic manner. It should be understood by those skilled in the art that the specific embodiment of the window sash driving device 13 is only an example and is not intended to limit the content and scope of the smart window 100 of the present invention.

Preferably, said sash driving device 13 is mounted to said lower window frame 112 of said window frame 11. Specifically, the lower window frame 112 has an installation space 1101 and a sliding slot 1102 communicating with the installation space 1101. The window sash driving device 13 is installed in the installation space 1101, the window sash 12 is movably installed in the sliding groove 1102, the window sash 12 is held above the window sash driving device 13, and the window sash driving device 13 supports the window sash 12 upward, facilitating smooth sliding of the window sash 12 relative to the window frame 11. Further, the window sash driving device 13 is hidden in the installation space 1101, which not only ensures the beauty of the smart window 100, but also prevents rain water or dust from eroding the window sash driving device 13.

Optionally, said sash driving means 13 is mounted to said upper window frame 111 of said window frame 11. Specifically, the upper window frame 111 has the installation space 1101 and the sliding groove 1102 communicating with the installation space 1101. The window sash driving device 13 is installed in the installation space 1101, and the window sash 12 is movably installed in the sliding groove 1102 of the upper window frame 111 in such a manner as to be held below the window sash driving device 13. It should be noted that the specific installation position of the window sash driving device 13 is only an example, and is not intended to limit the content and scope of the smart window 100 of the present invention. The window sash driving device 13 may be mounted to either the left window frame 113 or the right window frame 114.

Referring to fig. 2 to 11, the automatic screen window 20 includes a screen window frame 21, at least one screen assembly 22 and at least one screen driving device 23, wherein the screen assembly 22 is movably mounted on the screen window frame 21, the screen assembly 22 is connected to the screen driving device 23 in a driving manner, and the screen driving device 23 drives the screen assembly 22 to move relative to the screen window frame 21, so that the automatic screen window 20 can be switched between the unfolded state and the storage state.

In this embodiment of the present invention, the screen assembly 22 of the automatic screen window 20 comprises a receiving column 221 and a screen 222, wherein the screen 222 is wound around the receiving column 221 in such a manner that an inner end portion thereof is fixed to the receiving column 221, and an outer end portion of the screen 222 is connected to the screen 222 driving device 23. The gauze driving device 23 can drive the gauze 222 to be unfolded outwards in a way that the outer end part is far away from the receiving column 221, and shield the automatic window body 10, so that when the automatic window body 10 is in the opening state, the automatic window 20 in the unfolding state can prevent outdoor mosquitoes, flies and other insects from entering a room. The gauze 222 of the automatic screen window 20 in the storage state is rolled up in the storage column 222 in a manner that the outer end portion is close to the storage column 221, which not only reduces the volume of the automatic screen window 20, but also prevents the gauze 222 from shielding the automatic window 10 to influence the light transmission performance of the smart window 100.

Referring to fig. 2 to 11, in an embodiment of the present invention, the screen driving device 23 includes a screen driving motor 231, a screen belt 232, and a screen fixing member 233, wherein the screen belt 232 is drivingly connected to the screen driving motor 231, the screen fixing member 233 is installed to the screen belt 232, and the screen 22 is fixed to the screen fixing member 233. The screen driving motor 231 drives the screen conveying belt 232 to move and drives the outer end portion of the screen 22 to be far away from the storage column 221 or close to the storage column 221, so that the automatic screen window 20 can be switched between the unfolding state and the storage state.

Preferably, the receiving column 221 is rotatably connected to the screen driving motor 231, and the screen driving motor 231 can drive the receiving column 221 to rotate, so that the receiving column 221 can cooperate with the screen conveying belt 232 to unfold or receive the screen 222. Specifically, when the screen driving motor 231 drives the screen belt 232 to move in such a manner that the outer end portion of the screen 222 is away from the receiving column 221, the screen driving motor 231 synchronously drives the receiving column 221 to rotate clockwise, so that the automatic screen 20 is switched from the receiving state to the deployed state. When the screen driving motor 231 drives the screen conveying belt 232 to move in such a way that the outer end portion of the screen 222 approaches the receiving column 221, the screen driving motor 232 synchronously drives the receiving column 221 to rotate counterclockwise, so that the automatic screen window 20 is switched from the unfolded state to the received state, and the screen 222 is wound around the receiving column 221.

Optionally, a French spring is disposed inside the receiving column 221, and the screen 222 is mounted on the receiving column 221 by the French spring. Specifically, the screen 222 is wound around the storage column 221 such that an inner end portion thereof is fixed to the french spring, and when the screen driving motor 231 drives the screen belt 232 to move such that an outer end of the screen 222 moves away from the storage column 221, the screen 222 is unfolded, and the french spring provided in the storage column 221 is deformed to store elastic potential energy. When the screen driving motor 231 drives the screen belt 232 to move so that the outer end portion of the screen 222 approaches the receiving column 221, the elastic potential energy accumulated by the french spring is gradually released, and the screen is wound around the receiving column 221.

Alternatively, the screen driving device 23 is implemented as an electric push rod, and the screen driving device 23 drives the screen 222 to move relative to the screen window frame 21 in an electric telescopic manner. For example, the screen 222 moves left and right with respect to the screen window frame 21 in accordance with the expansion and contraction of the electric push rod, and is switched between the expanded state and the stored state. Alternatively, the screen driving device 23 is implemented as a hydraulic push rod, and the screen driving device 23 drives the screen 222 to move relative to the screen window frame 21 in a hydraulic telescopic manner. It should be understood by those skilled in the art that the specific embodiment of the screen driving device 23 is only an example and should not be construed as limiting the content and scope of the smart window 100 of the present invention.

Referring to fig. 2, the screen window frame 21 of the automatic screen 20 includes an upper screen window frame 211, a lower screen window frame 212 with respect to the upper screen window frame 211, a left screen window frame 213, and a right screen window frame 214 with respect to the left screen window frame 113, and the left screen window frame 213 and the right screen window frame 214 connect the upper screen window frame 211 and the lower screen window frame 212. The upper screen frame 211, the lower screen 212, the left screen frame 213, and the right screen frame 214 respectively have a receiving space 2101.

In a specific embodiment of the present invention, the screen driving unit 23 is installed in the receiving space 2101 of the lower screen window frame 212 or the receiving space 2101 of the upper screen window frame 211, and the screen assembly 22 is held in the receiving space 2101 of the left screen window frame 213 or the receiving space 2101 of the right screen window frame 214. The screen driving device 23 can drive the screen 222 of the screen assembly 22 to move left and right, so that the automatic screen 20 is switched between the unfolding state and the accommodating state.

Alternatively, the screen driving device 23 is installed in the receiving space 2101 of the left screen window frame 213 or the receiving space 2101 of the right screen window frame 214, and the screen assembly 22 is held in the receiving space 2101 of the lower screen window frame 212 or the receiving space 2101 of the upper screen window frame 211. The screen driving device 23 can drive the screen 222 of the screen assembly 22 to move up and down, so that the automatic screen 20 is switched between the deployed state and the storage state.

It is worth mentioning that the screen 222 of the screen assembly 22 of the automatic screen window 20 in the storage state is hidden in the accommodating space 2101 of the screen window frame 21 in a manner of being rolled up on the storage column 221, which not only reduces the volume of the automatic screen window 20, but also prevents the screen 222 of the automatic screen window 20 from shielding the window sash 12 of the automatic window 10, thereby improving the light transmittance of the smart window 10. Moreover, when the screen 222 is in the storage state, the screen 222 is hidden, so that the screen 222 is prevented from being exposed to the air for a long time, which is beneficial to prolonging the service life of the automatic screen window 20 and reducing the use cost and maintenance cost of the automatic screen window 20.

Preferably, the screen assembly 22 of the automatic screen window 20 further includes a protective case 223, wherein the protective case 223 has a receiving space 22301 and a side opening 22302 communicating with the receiving space 22301, the receiving column 221 and the screen 222 are held in the receiving space 22301, and an outer end of the screen 222 can extend outward from the side opening 22302. The screen 222 of the automatic screen window 20 in the storage state can be hidden in the storage space 22301, so as to reduce the contact between air and water vapor in the external environment and further facilitate to prolong the service life of the automatic screen window 20.

In this particular embodiment of the utility model, the automotive screen 20 further comprises a closure assembly 24, wherein the closure assembly 24 comprises an active closure 241 and a passive closure 242, wherein the active closure 241 and the passive closure 242 are mounted to the outer end of the screen 222 and the screen frame 21, respectively. The active closure 241 is removably attached to the passive closure 242 such that the outer end of the screen 222 is removably attached to the screen window frame 21.

Further, the active closure 241 extends from the upper edge of the screen 222 to the lower edge of the screen, and the length of the passive closure 242 corresponds to the length of the active closure 241. After the active closing part 241 is attached to the passive closing part 242, the automatic screen 20 is in the unfolded state, the screen 222 completely blocks the window sash 12 of the automatic window 10 and the opening formed between the window sash 12 and the window frame 11, and the active closing part 241 and the passive closing part 242 are closely attached to prevent a gap from being generated between the screen 222 and the screen frame 21, so as to prevent mosquitoes and flies in the external environment from entering the room from between the screen 222 and the screen frame 21.

Preferably, the active closing element 241 and the passive closing element 242 are implemented as soft magnetic strips, the passive closing element 242 being detachably attached by means of magnetic attraction. In the process of switching the automatic screen 20 from the storage state to the unfolding state, the active closing member 241 provided at the outer end portion of the screen mesh 222 moves toward the passive closing member 242, and the active closing member 21 can automatically magnetically attract the passive closing member 242, so that the outer end portion of the screen mesh 222 is connected to the screen window frame 21 in a closing manner. When the gauze driving device 23 drives the gauze 222 to move reversely, the active closing part 21 and the passive closing part 242 are separated.

Alternatively, the active closing element 241 is implemented as an elastic deformation element, such as but not limited to rubber and silicon, etc., and the passive closing element 242 is an elongated protrusion extending from the inner wall of the window frame 21 into the accommodating space 2101. The active closing member 21 is moved to contact the passive closing member 242, and then moves forward, the passive closing member 242 prevents the contact portion of the active closing member 21 from moving forward, and after the active closing member 21 wraps the passive closing member 242 in an elastically deformed manner, the screen driving device 23 stops operating, and at this time, the active closing member 21 and the passive closing member 242 cooperate with each other to prevent a gap from being generated between the outer end of the screen 222 and the screen window frame 21. After the automatic screen 20 is switched from the deployed state to the stowed state, the active closure 21 releases the elastic potential energy and restores the initial state.

Alternatively, the active closing element 241 and the passive closing element 242 of the closing assembly 24 may also be embodied as suction cups or the like. It should be understood by those skilled in the art that the specific embodiments of the active closure 241 and the passive closure 242 are interchangeable, and that the specific embodiments of the active closure 241 and the passive closure 242 are only exemplary and should not be construed as limiting the scope and content of the smart window 100 of the present invention.

Referring to fig. 2 to 11, in a specific embodiment of the present invention, the screen assembly 22 and the screen driving means 23 of the automatic screen 20 are implemented as one, and the automatic screen 20 is a one-piece structure. For example, one of the screens 222 of the screen assembly 22 of the motorized screen 20 may extend from the left window frame 213 to the right window frame 214. Alternatively, one of the screens 222 of the screen assembly 22 of the automotive screen 20 may extend from the upper side window frame 211 to the lower side window frame 212.

Referring to fig. 12 and 13, alternatively, the screen assemblies 22 and the screen driving means 23 of the automatic screen 20 are implemented in two, the automatic screen 20 is a two-piece structure, and the active closing member 241 and the passive closing member 242 are respectively provided at outer ends of the screens 222 of the two screen assemblies 22.

For example, the screen 222 of the screen assembly 22 mounted to the left side frame 213 may cover the window sash 12 and the opening between the window sash 12 and the window frame 11 on the left side, and the screen 22 of the screen assembly 22 mounted to the right side frame 214 may cover the window sash 12 and the opening between the window sash 12 and the window frame 11 on the right side. When the automatic window screen 20 is in the storage state, the screen 222 of one screen assembly 22 is hidden in the accommodating space 2101 of the left side window frame 213, and the screen 222 of the other screen assembly 22 is hidden in the right accommodating space 21401 of the right side bed frame 214. When the automatic screen window 20 is switched from the storage state to the expansion state, the two screen driving devices 23 drive the screens 222 of the two screen assemblies 22 to move relatively, and after the active closing member 241 and the passive closing member 242 are attached to each other, the automatic screen window 20 completely blocks the window sash 12 of the automatic window 10 and the opening between the window sash 12 and the window bed frame 11, and the automatic screen window 20 is switched to the expansion state. When the automatic screen window 20 is switched from the unfolded state to the storage state, the two screen driving devices 23 drive the screens 222 of the two screen assemblies 22 to move away from each other.

In this particular embodiment of the present invention, the automatic screen window 20 can switch its own working state according to the working state of the automatic window 10 to provide better user experience. Specifically, when the automatic window 10 is switched from the closed state to the open state, the automatic screen 20 is switched from the storage state to the deployed state in response to the automatic window 10, so as to block the opening between the window sash 12 and the window frame 11 of the automatic window 10, and prevent mosquitoes and flies from entering the room. When the automatic window 10 is switched from the open state to the closed state, the automatic screen 20 is switched from the expanded state to the storage state in response to the automatic window 10, so as to avoid shielding the window sash 12. That is, the automatic window screen 20 and the automatic window 10 of the smart window 100 are not only structurally integrated, but also the automatic window 10 and the automatic window sash 20 are capable of cooperating with each other, so as to intelligently create a more comfortable indoor environment, which is beneficial to improving the aesthetic property and intelligence of the smart window 100.

Further, referring to fig. 5 to 7, the automatic window 10 of the smart window 100 can intelligently adjust the working state according to an environmental factor, which is beneficial to creating a more comfortable and healthy indoor environment. In particular, said smart window 100 further comprises at least one environmental factor detecting device 30, wherein said environmental factor detecting device is communicably connected to said automatic window 10, said environmental factor detecting device 30 is used for detecting said environmental factor, and said automatic window 10 automatically adjusts its working status according to the detection result of said environmental factor detecting device 30. For example, but not limited to, the automatic window 10 is switched from the closed state to the open state according to the environmental factor, the automatic window 10 is switched from the open state to the closed state, the automatic window 10 in the open state automatically adjusts a distance between the window sash 12 and the window sash frame 11, changes a size of the opening formed between the window sash 12 and the window sash frame 11, and the like.

Referring to fig. 5, the environmental factor detection device 30 includes at least one temperature sensor 31, the temperature sensor 31 is installed inside and/or outside the automatic window 10, and the temperature sensor 31 is communicably connected to the automatic window 10. Preferably, the temperature sensors 31 are implemented in two, and two temperature sensors 31 are respectively installed at the outer side of the window frame 11 of the automatic window 10 and the inner side of the screen frame 21 of the automatic screen 20. The two temperature sensors 31 are used for detecting indoor and outdoor temperatures, a preset temperature and/or a preset temperature condition are/is preset in each of the two temperature sensors 31, and when the two temperature sensors 31 detect that the outdoor temperature and the indoor temperature meet the preset temperature and the preset temperature condition, the automatic window 10 automatically adjusts the working state of the automatic window. For example, the preset temperature is implemented as 24 ℃, and when the indoor temperature detected by the temperature sensor 31 for detecting the indoor temperature is lower than 24 ℃, and the outdoor temperature detected by the temperature sensor 31 for detecting the outdoor temperature is higher than 24 ℃, the automatic window 10 automatically switches from the closed state to the open state, so as to increase the indoor temperature.

Alternatively, referring to fig. 7, the temperature sensor 31 may be implemented as one, and one of the temperature sensors 31 is installed at the outer side of the automatic window 10 or the inner side of the automatic screen 20. The automatic window 10 automatically adjusts an operation state according to a temperature change outdoors or indoors. It should be understood by those skilled in the art that the specific number of the temperature sensors 31, the preset temperature and the specific implementation of the preset condition are only examples and should not be construed as limiting the content and scope of the smart window 100 of the present invention.

Referring to fig. 5, the environmental factor sensor 30 includes at least one humidity sensor 32. Preferably, two of the humidity sensors 32 are installed at an outer side of the window frame 11 of the automatic window 10 and an inner side of the screen frame 21 of the automatic screen 20, and the humidity sensors 32 are communicably connected to the automatic window 10. Two humidity transducer 32 is used for detecting outdoor air humidity and indoor air humidity respectively, and two temperature sensor 31 is preset one respectively and is predetermine humidity and one and predetermine the humidity condition, works as two humidity transducer 31 detects that outdoor air humidity and indoor air humidity accord with predetermine humidity and/or when predetermineeing the humidity condition, automatic window body 10 adjusts the operating condition of self automatically.

For example, when the humidity change detected by the humidity sensor 32 detecting the humidity of the outdoor air is suddenly increased but the humidity change detected by the humidity sensor 32 detecting the humidity of the indoor air is small when the automatic window 10 is in the open state, the automatic window 10 is automatically switched from the open state to the closed state. Thus, when raining suddenly, the automatic window 10 can be automatically closed, and rainwater is prevented from entering the room.

Alternatively, the humidity sensor 32 may be implemented as one, and one of the humidity sensors 32 is used to detect the humidity change of the outdoor air. It should be understood by those skilled in the art that the specific number of humidity sensors 32, the specific implementation of the preset temperature and the preset condition are only examples and should not be construed as limiting the content and scope of the smart window 100 of the present invention.

Referring to fig. 6, the environmental factor sensor 30 includes at least one dust sensor 33. Preferably, two dust sensors 33 are installed at an outer side of the window frame 11 of the automatic window 10 and an inner side of the screen frame 21 of the automatic screen 20, and the dust sensors 33 are communicably connected to the automatic window 10. Two dust sensor 33 is arranged in detecting the dust concentration in outdoor and indoor air respectively, and two dust sensor 33 is preset a concentration and a concentration condition, and when two dust sensor 33 detects that dust concentration in the indoor air and dust concentration in the indoor air accord with preset humidity and/or when presetting the humidity condition, automatic window 10 automatically adjusts self operating condition.

For example, when the dust sensor 33 for detecting the dust concentration in the outdoor air detects that the dust concentration in the outdoor air is greater than the preset concentration with the automatic window 10 in the open state, the automatic window 10 automatically switches from the open state to the closed state. Therefore, in haze weather, the automatic window body 10 is automatically switched from the open state to the closed state, and dust in outdoor air are reduced to enter the indoor space. Or, when the dust concentration in the indoor air is detected to be greater than the preset concentration under the condition that the automatic window 10 is in the open state, the automatic window 10 is automatically switched from the closed state to the open state. Therefore, if the oil smoke in the kitchen is too large or the indoor gas leaks, the automatic window body 10 can be automatically opened, so that the indoor air is prevented from being turbid, and the possibility of dust inhalation of a human body is reduced.

Alternatively, the preset concentration condition of the dust sensor 33 may also be set, but not limited to, a priority including a concentration in indoor air and a concentration in outdoor air, and the like. Alternatively, the dust sensor 33 may be implemented as one, and the dust sensor 33 is only used for detecting the dust concentration in the outdoor or indoor air. It should be understood by those skilled in the art that the specific number of dust sensors 33, the preset concentration and the specific implementation of the preset concentration condition are only examples and should not be construed as limiting the content and scope of the smart window 100 of the present invention.

Preferably, referring to fig. 6, the environmental factor detecting device 30 includes at least one wind sensor 34, wherein the wind sensor 34 is mounted to the window frame 11 of the automatic window 10, and the wind sensor 34 is communicably connected to the automatic window 10. The wind sensors 34 are used for detecting outdoor wind power, a preset wind power value and a preset wind power condition are preset in the wind sensors 34, and when the two wind sensors 34 detect that the outdoor wind power meets the preset wind power value and/or the preset wind power condition, the automatic window 10 automatically adjusts the working state of the automatic window.

For example, when the outdoor wind force detected by the wind sensor 34 detecting the dust concentration in the outdoor air is greater than the preset wind force value with the automatic window 10 in the open state, the automatic window 10 automatically switches from the open state to the closed state. Thus, if the window body meets typhoon, the automatic window body 10 can be automatically closed, and the damage of outdoor gust to indoor ornaments or furniture is reduced. It should be understood by those skilled in the art that the specific number of the wind sensors 34, the preset wind force value and the specific implementation of the preset wind conditions are only examples and should not be construed as limiting the content and scope of the smart window 100 of the present invention.

Preferably, referring to fig. 7, said environmental factor detection means 30 comprises at least one rain sensor 35, wherein said rain sensor 35 is mounted on the outside of said window frame 11 of said automatic window 10, said rain sensor 35 being communicatively connected to said automatic window 10. The rainfall sensor 35 is used for detecting whether the outdoor rain falls or not and the magnitude of the outdoor rainfall, a preset rainfall value and a preset rainfall condition are preset in the rainfall sensor 34, and when the two wind sensors 34 detect that the magnitude of the outdoor rainfall meets the preset rainfall value and/or the preset rainfall condition, the automatic window 10 automatically adjusts the working state of the automatic window.

For example, when the rainfall sensor 35 detects that rainfall begins outdoors, the automatic window 10 automatically switches from the open state to the closed state, and when the rainfall sensor 35 does not detect rainfall outdoors, the automatic window 10 switches from the closed state to the open state. Or, when the rainfall sensor 35 detects outdoor rainfall but the rainfall is small, the automatic window 10 reduces the size of the opening formed between the window sash 12 and the window frame 11, but still maintains the automatic window 10 in the open state, ensuring indoor ventilation and light transmission; when the detected amount of rainfall is large, the automatic window 10 continues to reduce the size of the opening formed between the window sash 12 and the window frame 11 until the automatic window 10 is in the closed state.

Referring to fig. 8, in a specific embodiment of the present invention, the automatic window 10 of the smart window 100 is communicably connected to an air treatment device 200 indoors, wherein the automatic window 10 switches its operation state according to a change in the operation state of the air treatment device 200. In particular, the air treatment device 200 may be embodied as, but not limited to, an air conditioner, an air purifier, an air humidifier, a warm air blower, an air cooler, and the like. With the automatic window 10 in the open state, when the air treatment device 200 switches from a closed state to an operational state, the automatic window 10 automatically switches from the open state to the closed state. In this way, the working efficiency of the air treatment device 200 is improved, and the electric energy consumption is saved. The manner in which the automatic window 10 is communicatively coupled to the air treatment device 200 is such as, but not limited to, a wired connection or a wireless connection, etc.

Referring to fig. 9, in a specific embodiment of the present invention, the smart window 100 further includes a fresh air device 40, wherein the fresh air device 40 is installed at the window frame 11 of the automatic window 10 and the screen frame 21 of the automatic screen 20, and the fresh air device 40 is communicably connected to the automatic window 10. The fresh air device 40 can switch its own working state according to the working state of the automatic window 10. Specifically, after the automatic window 10 is switched from the open state to the closed state, the fresh air device 40 is switched from the closed state to the operating state in response to the automatic window 10. The fresh air device 40 in the operating state guides outdoor air into the room and discharges the indoor air out of the room, so that the purification and the flow of the indoor air are promoted, a good indoor environment is created, and the phenomenon of air turbidity caused by the fact that the room is in a closed state for a long time is avoided.

Referring to fig. 10, in a specific embodiment of the present invention, the smart window 100 further includes a self-cleaning device 50, wherein the self-cleaning device 50 is mounted on the outer surface of the window sash 12 of the automatic window 10, and the self-cleaning device 50 can automatically clean the outer surface of the window sash 12, so as to keep the window sash 12 clean, thereby ensuring the aesthetic appearance of the window sash 12 and ensuring good light transmittance of the window sash 12. Further, the self-cleaning device 50 is communicably connected to the automatic window 10, and the automatic window 10 and the self-cleaning device 50 cooperate to comprehensively clean the light-transmitting surface of the window sash 12. For example, but not limiting of, the self-cleaning device 50 may clean the outer surface of the window sash 12 by cleaning a brush, vacuuming, spraying, etc.

Preferably, the self-cleaning device 50 detects the dirt on the surface of the window sash 12, when the dirt on the outer surface of the window sash 12 reaches a cleaning alarm value, the automatic window 10 is kept in the closed state, and the self-cleaning device 50 automatically cleans the outer surface of the window sash 12.

Optionally, the operation frequency and operation time of the self-cleaning device 50 are preset, for example, the self-cleaning device 50 is preset to clean once per week, when the self-cleaning device 50 reaches the preset operation time, the automatic window 10 is kept in the closed state, and the self-cleaning device 50 cleans the outer surface of the window sash 12.

Referring to fig. 11, in a specific embodiment of the present invention, the smart window 100 further includes a control device 60, wherein the control device 60 is communicably connected to the automatic window 10 and the automatic screen 20, and the operation state 20 of the automatic window 10 and the automatic screen 20 can be adjusted by operating the control device 60.

Preferably, said control means 60 is mounted to said screen window frame 21 of said automotive screen 20. For example, the control device 60 is a touch screen display, and the user can adjust the operation states of the automatic window 10 and the automatic screen 20 by selecting different operation modes. Alternatively, the control means 60 is a hand-held remote control, and the user can remotely control the automatic screen 20 and the automatic window 10.

Alternatively, the user may set a personal mode through the control device 60, for example, the personal mode may include, but is not limited to, the preset temperature and the preset temperature condition of the temperature sensor 31, the preset humidity and the preset humidity condition of the humidity sensor 32, the preset concentration and the preset concentration condition of the dust sensor 33, the preset wind force value and the preset wind force value condition of the wind force sensor 34, the size of the opening formed between the window sash 12 and the window frame 11 when the automatic window 10 is in the open state, and the like.

Preferably, referring to fig. 11, the smart window 100 further comprises a communication device 70, wherein the communication device 70 is communicably connected to the automatic window 10, the automatic window 20, the temperature sensor 31, the humidity sensor 32, the dust sensor 33, the wind sensor 34, the fresh air device 40 and the self-cleaning device 50 of the environmental factor detecting device 30, and the communication device 70 is allowed to be communicably connected to an electronic device 300, by means of the communication device 70, the smart window 100 can connect the working states of the automatic window 10, the automatic window 20, the temperature sensor 31, the humidity sensor 32, the dust sensor 33, the wind sensor 34, the fresh air device 40 and the self-cleaning device 50 to the automatic window 10, the automatic window 20, the environmental factor detecting device 30, The operating parameters, the detection data, and the like are transmitted to the electronic device 300. The user can check the indoor and outdoor temperature and humidity, the dust concentration, etc. through the electronic device 300, and also can control the working states of the automatic window 20 and the automatic window 10 by operating the electronic device. For example, but not limited to, the communication device 70 is wirelessly connected to the electronic device 300 by bluetooth, wifi, NFC, 2G, 4G, 5G, etc.

Preferably, referring to fig. 11, the smart window 100 further includes a storage device 80, wherein the storage device 80 is communicably connected to the automatic window 10, the automatic screen 20, the temperature sensor 31 of the environmental factor detecting device 30, the humidity sensor 32, the dust sensor 33, the wind sensor 34, the fresh air device 40, the self-cleaning device 50, and the control device 60. The storage device 80 stores the working state changes, working parameters, detection data, and the like of the automatic window 10, the automatic screen 20, the temperature sensor 31, the humidity sensor 32, the dust sensor 33, the wind sensor 34, the fresh air device 40, the self-cleaning device 50, and the control device 60 of the environmental factor detection device 30.

Preferably, after the user controls the automatic window 10 and the automatic screen 20 using the control device 60, the storage device 80 can memorize and generate a user habit pattern to allow the user to directly select the next time of use.

It will be appreciated by persons skilled in the art that the above embodiments are only examples, wherein features of different embodiments may be combined with each other to obtain embodiments which are easily conceivable in accordance with the disclosure of the utility model, but which are not explicitly indicated in the drawings.

It will be appreciated by persons skilled in the art that the embodiments of the utility model described above and shown in the drawings are given by way of example only and are not limiting of the utility model. The objects of the utility model have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the examples, and any variations or modifications of the embodiments of the present invention may be made without departing from the principles.

Claims (10)

1. A smart window, comprising:

an automotive screen, wherein the automotive screen comprises a screen window frame, at least one screen assembly, at least one screen driving device, an active closing member and a passive closing member, wherein the screen assembly and the screen drive are mounted to the screen window frame, the screen drive being drivingly connected to the screen drive, the screen drive being capable of driving the screen assembly relative to the screen window frame, and allows the automatic screen to be switched between an expanded state and a stored state, the screen assembly including a storage post and a screen disposed in the storage post, the active closure being provided on one of the screens, the passive closure being provided on the other of the screens or screen window frames, the active closure is removably attached to the passive closure when the automated screen is in the deployed state.

2. The smart window of claim 1, wherein the screen window frame has a receiving space, wherein the screen assembly and the screen driving device are held in the receiving space, the smart window further comprising an automatic window, wherein the automatic screen is held at one side of the automatic window, the automatic screen is communicably connected to the automatic window, the automatic window is automatically switchable between an open state and a closed state, the automatic screen is automatically adjusted to the open state when the automatic window is in the open state, and the automatic screen is automatically adjusted to the storage state when the automatic window is in the closed state.

3. The smart window of claim 2, wherein the screen assembly includes a receiving post and a screen movably wound about the receiving post with an inner end of the screen secured to the receiving post, an outer end of the screen being connected to the screen drive, the screen drive being capable of driving the screen to move relative to the receiving post to allow the automatic window to be switchable between the open state and the received state.

4. The smart window of claim 3, wherein the screen drive comprises a screen drive motor, a screen belt drivingly connected to the screen drive motor, and a screen mount mounted to the belt, the screen being secured to the screen mount, the receiving posts of the screen assembly being drivingly rotationally connected to the screen drive motor.

5. The smart window of claim 3, wherein the active closure is provided to the screen, the passive closure is provided to the screen window frame, the active closure of the automatic screen in the deployed state automatically magnetically attracts the passive closure, wherein the screen assembly and the screen driving device of the automatic screen are implemented as one, the automatic screen being a one-piece structure; or the screen components and the screen driving devices of the automatic screen window are implemented in two, the automatic screen window is in a two-piece structure, the active closing piece and the passive closing piece are respectively arranged on the screens of the two screen components, and the active closing piece of the automatic screen in the unfolding state is automatically magnetically attracted to the passive closing piece.

6. The smart window of claim 3, wherein the screen assembly further comprises a protective housing, wherein the protective housing has a receiving space communicated with a side opening of the receiving space, wherein the screen is held in the receiving space of the protective housing, and the screen is extendable outward from the side opening.

7. A smart window according to claim 3, wherein the automatic window comprises a window frame having an installation space, at least one sash and at least one sash driving device mounted in the installation space of the window frame, the sash being connected to the sash driving device in such a way as to be movably mounted to the window frame, the sash driving device being capable of driving the sash to move relative to the window frame to allow the automatic window to be switchable between the open state and the closed state.

8. The smart window of claim 7, wherein the sash drive of the automated window comprises a sash drive motor, a sash conveyor belt drivingly connected to the sash drive motor, and a sash mount mounted to the sash conveyor belt, the sash connected to the sash mount.

9. The smart window according to any one of claims 2 to 8, further comprising an environmental factor detecting device, wherein the environmental factor detecting device is communicably connected to the automatic window, and the automatic window automatically adjusts an operation state according to an environmental factor detected by the environmental factor detecting device, wherein the environmental factor detecting device is selected from the group consisting of a temperature sensor, a humidity sensor, a dust sensor, a wind sensor, and a rainfall sensor.

10. The smart window of claim 9, further comprising a storage device, wherein the storage device is communicably connected to the automatic window, the automatic screen, and the environmental factor detection device, the storage device allowing storage of a detection result of the environmental factor detection device and a change in operation state of the automatic window and the automatic screen.

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