CN109199057B

CN109199057B - A variable curtain structure

Info

Publication number: CN109199057B
Application number: CN201811187937.9A
Authority: CN
Inventors: 白智文
Original assignee: Jiaxing Nottingham Industrial Design Co ltd
Current assignee: Hubei Xiongye New Material Technology Co ltd
Priority date: 2018-10-12
Filing date: 2018-10-12
Publication date: 2021-07-13
Anticipated expiration: 2038-10-12
Also published as: CN109199057A

Abstract

The invention relates to a variable curtain structure, which belongs to the field of household products. To sum up, in the variable curtain structure provided by the present invention, the processor receives the signal instruction received by the signal receiving device, and controls the positional relationship of each curtain fabric on each track in the variable sliding rail, thereby realizing the updating of indoor and outdoor curtain fabrics , which can improve the user's visual experience of the curtain structure; in addition, by controlling the degree of expansion and contraction of each curtain, the degree of blocking of the external light can be adjusted, so as to adjust the intensity of the indoor light, and the adjustment of the light is not local adjustment , to ensure the integrity of the indoor light; finally, through the switching of the positional relationship of the curtain fabrics of different materials, the adjustment of the indoor temperature by the curtain fabric structure can also be realized.

Description

Variable curtain structure

Technical Field

The invention relates to the field of household articles, in particular to a variable curtain structure.

Background

When a room is decorated, a user often designs a pair of curtains beside a glass window, so that the requirement of the user for adjusting the indoor natural light intensity is met.

Existing window shade structures generally include a roller blind or a sliding window shade, and the window shade fabric is generally a single-layer nonwoven fabric or a composite nonwoven fabric. When a user uses the rolling curtain, the shielding area of the curtain cloth on a window can be controlled by pulling the curtain rope under the rolling device, and the natural illumination intensity in an incident room is further controlled; when a user uses the sliding type curtain, the curtain cloth can be pulled to the left side and the right side to be folded to control the shielding area of the curtain cloth on the window, and then the natural illumination intensity in an incident room is controlled.

The inventor finds out in the process of using the existing curtain structure that:

the existing curtain structure can only control the irradiation area of natural light entering the room, so that the indoor light degree is uneven and the light quality is poor; moreover, the curtain structure can only introduce natural light in a single form, so that the indoor light is only selected from bright light and dark light; the curtain cloth pattern is fixed, and the function is comparatively single, can't satisfy the demand experience of user to the freshness.

Disclosure of Invention

In order to solve the problems related to the prior art, the invention provides a variable curtain structure.

According to an aspect of an embodiment of the present invention, there is provided a variable window covering structure, wherein the window covering structure includes a first curtain cloth, a second curtain cloth, a third curtain cloth, a mounting guard plate, a variable slide rail, a signal receiving device, and a processor;

the variable slide rail comprises a first rail, a second rail, a third rail and six transfer rails, wherein transfer openings are formed in preset positions on the transfer rails;

the upper end of the first curtain cloth is fixed on the first rail through a first pulley block, the upper end of the second curtain cloth is fixed on the second rail through a second pulley block, and the upper end of the third curtain cloth is fixed on the third rail through a third pulley block;

the signal receiving device and the processor are arranged on one side of the variable sliding rail, the processor is respectively electrically connected with the signal receiving device, the first pulley block, the second pulley block and the third pulley block, and the processor is used for receiving a signal instruction received by the signal receiving device and controlling the first pulley block, the second pulley block and the third pulley block to move along each rail according to a preset rule according to the received signal instruction;

the first curtain cloth, the second curtain cloth, the third curtain cloth, the variable slide rail, the signal receiving device and the processor are arranged in the installation protection plate.

In a preferred embodiment, the surface of the first curtain cloth is coated with a radiation-proof coating, the second curtain cloth is made of a heat-conducting material, and the surface of the third curtain cloth is coated with a heat-dissipating coating.

In a preferred embodiment, the heat-dissipating coating composition comprises: ethyl acetate, graphene, aluminum oxide, epoxy resin, a stabilizer and a heat radiating agent.

In a preferred embodiment, the radiation protective coating composition comprises: talcum powder, glass powder, aluminum phosphate, titanium dioxide, mica powder and carbon nano tubes.

In a preferred embodiment, the thicknesses of the first cord fabric, the second cord fabric and the third cord fabric are 0.23-0.30cm, 0.18-0.23cm and 0.15-0.18cm in sequence.

In a preferred embodiment, different types of patterns are painted on the first curtain cloth, the second curtain cloth and the third curtain cloth respectively.

In a preferred embodiment, the size of the respective transfer opening is larger than the size of the individual pulleys of the respective pulley block.

The technical scheme provided by the embodiment of the invention can have the following beneficial effects:

according to the variable curtain structure, the processor receives the signal instruction received by the signal receiving device, and the position relation of each curtain cloth in each track in the variable sliding rail is controlled, so that indoor and outdoor curtain cloth updating is realized, and the visual experience of a user on the curtain structure can be improved; in addition, the adjustment of the blocking degree of the external light can be realized by controlling the stretching degree of each curtain cloth, so that the intensity of the indoor light is adjusted, and the adjustment of the light is not locally adjusted, so that the integration of the indoor light is ensured; finally, the curtain cloth structure can also adjust the indoor temperature by switching the position relation of the curtain cloth made of different materials.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

FIG. 1 is a schematic view of a variable blind construction according to an exemplary embodiment.

Fig. 2 is a schematic view illustrating a state of a variable blind structure according to an exemplary embodiment.

FIG. 3 is a schematic view of another variable blind configuration according to an exemplary embodiment.

FIG. 4 is a schematic view illustrating a state of yet another variable blind structure according to an exemplary embodiment.

FIG. 5 is a schematic view of a state of yet another variable blind structure according to an exemplary embodiment.

FIG. 6 is an illustration showing a variable blind structure according to an exemplary embodiment.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present invention. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the invention, as detailed in the appended claims.

FIG. 1 is a schematic view of a variable blind construction according to an exemplary embodiment. As shown in fig. 1, the window covering structure includes a first curtain cloth 100, a second curtain cloth 200, a third curtain cloth 300, a mounting guard 400, a variable slide rail 500, a signal receiving device 600 and a processor 700;

the variable slide rail 500 comprises a first rail 510, a second rail 520, a third rail 530 and six transfer rails 540, wherein transfer openings are arranged at preset positions on each transfer rail 540;

the upper end of the first curtain cloth 100 is fixed on the first rail 510 through a first pulley block 550, the upper end of the second curtain cloth 200 is fixed on the second rail 520 through a second pulley block 560, and the upper end of the third curtain cloth 300 is fixed on the third rail 530 through a third pulley block 570;

the signal receiving device 600 and the processor 700 are disposed on one side of the variable slide rail 500, the processor 700 is electrically connected to the signal receiving device 600, the first pulley block 550, the second pulley block 560 and the third pulley block 570, respectively, and the processor 700 is configured to receive a signal instruction received by the signal receiving device 600 and control the first pulley block 550, the second pulley block 560 and the third pulley block 570 to move along each track according to a preset rule according to the received signal instruction;

the first curtain cloth 100, the second curtain cloth 200, the third curtain cloth 300, the variable slide rail 500, the signal receiving device 600, and the processor 700 are disposed in the installation guard 400.

It should be noted that each of the first pulley block 550, the second pulley block 560, and the third pulley block 570 includes at least two pairs of pulleys, one pair of pulleys in the first pulley block 550 is fixed to one end of the first curtain cloth 100, and the other pair of pulleys is fixed to the other end of the first curtain cloth 100; one pair of pulleys in the second pulley block 560 is fixed at one end of the second curtain cloth 200, and the other pair of pulleys is fixed at the other end of the second curtain cloth 200; one pair of pulleys in the third pulley block 570 is fixed to one end of the third fabric 300, and the other pair of pulleys is fixed to the other end of the third fabric 300.

The processor 700 may control at least two pairs of pulleys of the pulley sets to independently move along the track, for example, the first pulley set 550 is located on the first track 510, and the processor 700 may control the left pulley of the first pulley set 550 to slide along the right side of the first track 510, and the right pulley to remain stationary, thereby enabling the first curtain 100 to retract; for another example, the first pulley block 550 is located on the first rail 510, the processor 700 controls the left pulley of the first pulley block 550 to slide along the right side of the first rail 510, controls the right pulley to enter the transfer rail 540 from the first rail 510, and then enter the third rail 530, and then the left pulley also enters the third rail 530 through the transfer rail 540, so as to realize that the first curtain 100 is changed from the position corresponding to the first rail 510 to the position corresponding to the third rail 530, and similarly, the third curtain 300 can also realize that the position corresponding to the third rail 530 is changed to the position corresponding to the first rail 510.

Through the change of the positions of the curtain cloth, the type of the curtain cloth on the outer layer of the variable curtain structure and the type of the curtain cloth on the inner layer are changed, so that the curtain cloth on the inner layer and the curtain cloth on the outer layer are updated simultaneously, and the visual aesthetic fatigue of a user is avoided.

A user can send a signal instruction to the signal receiving device through a mobile terminal client or a remote control terminal device matched with the signal receiving device 600 in the variable curtain structure provided by the embodiment of the invention, the signal receiving device 600 transmits the signal instruction to the processor 700 after receiving the signal instruction, and the processor 700 controls each pulley block to move along each track according to a preset rule according to the signal instruction, so as to control the extension, contraction or position exchange of each curtain.

The signal instruction sent by the user may be used to instruct the first pulley block 550, the second pulley block 560, and the third pulley block 570 to move independently on the respective tracks, or control the first pulley block 550, the second pulley block 560, and the third pulley block 570 to perform track change through the transfer track 540, so as to implement independent extension and retraction of the first curtain 100, the second curtain 200, and the third curtain 300, or implement change of the arrangement order among the first curtain 100, the second curtain 200, and the third curtain 300.

For example, the signal command sent by the user is used to instruct the first pulley block 550 to move on the first track 510, so that the first curtain cloth 100 is contracted, and the second pulley block 560 and the third pulley block 570 remain unchanged, at this time, the first curtain cloth 100 on the outer layer is in a contracted state, the second curtain cloth 200 on the middle layer is in an extended state, and the third curtain cloth 300 on the inner layer is in an extended state, at this time, the state diagram of the variable curtain structure is shown in fig. 2.

For another example, based on fig. 2, the signal command sent again by the user is used to instruct the second pulley block 560 to move on the second track 520, so that the second fabric 200 is contracted, while the first pulley block 550 and the third pulley block 570 remain unchanged, at this time, the first fabric 100 in the outer layer is in a contracted state, the second fabric 200 in the middle layer is in a contracted state, and the third fabric 300 in the inner layer is in an extended state, at this time, the state diagram of the variable curtain structure is shown in fig. 3.

For another example, based on fig. 3, the signal command sent again by the user is used to instruct the third pulley block 570 to move on the third track 530, so that the third fabric 300 is contracted, while the first pulley block 550 and the second pulley block 560 remain unchanged, at this time, the first fabric 100 in the outer layer is in a contracted state, the second fabric 200 in the middle layer is in a contracted state, and the third fabric 300 in the inner layer is also in a contracted state, at this time, the state diagram of the variable window shade structure is shown in fig. 4.

In the state diagrams of the variable window covering structures shown in fig. 1, 2, 3, and 4, the blocking ability of the variable window covering structures against light rays is sequentially reduced, and the intensity of the corresponding indoor light rays is sequentially increased. According to the variable curtain structure provided by the embodiment of the invention, the overall light intensity can be adjusted by controlling each layer of curtain cloth, but the existing curtain structure can only block local light, so that the indoor light quality is better and the integrity is stronger.

In order to better understand the method for using the variable window covering structure provided by the embodiment of the present invention, a schematic view of another variable window covering structure shown in fig. 5 is also shown, and it should be noted that in fig. 5, the first curtain cloth 100 and the third curtain cloth 300 are in a state of interchanging track positions.

In a preferred embodiment, the first cord fabric 100 is coated with a radiation-proof coating, the second cord fabric 200 is made of a heat-conducting material, and the third cord fabric 300 is coated with a heat-dissipating coating.

It should be noted that, by coating coatings with different functions on each layer of curtain cloth or by using raw materials with different materials, the function switching can be realized by the variable curtain structure provided by the embodiment of the present invention.

For example, the first fabric 100 is located close to the window, the surface of the first fabric 100 is coated with a radiation-proof coating, the second fabric 200 is made of a heat-conducting material, and the surface of the third fabric 300 is coated with a heat-dissipating coating. When the external environment temperature is high and the light is strong, a user can control the first curtain cloth 100 to be in an extended state on the first rail 510, the second curtain cloth 200 to be in an extended state on the second rail 520 and the third curtain cloth 300 to be in an extended state on the third rail 530, so that when external light irradiates the first curtain cloth 100, most of the radiation light is reflected by the radiation-proof coating of the first curtain cloth 100, heat brought by the external light is blocked, and the indoor temperature is kept at a cool degree; when the external environment temperature is low and the light is weak, the user can control the first curtain cloth 100 to switch to the position corresponding to the third track 530 and switch the third curtain cloth 300 to the position corresponding to the first track 510, so that when the external light irradiates the third curtain cloth 300, the heat dissipation coating of the third curtain cloth 300 absorbs the light and converts the light into heat energy, and the heat energy is transmitted to the first curtain cloth 100 through the second curtain cloth 200 and is dispersed indoors, thereby increasing the indoor temperature.

In a preferred embodiment, the thicknesses of the first cord fabric 100, the second cord fabric 200 and the third cord fabric 300 are 0.23-0.30cm, 0.18-0.23cm and 0.15-0.18cm in sequence.

In a preferred embodiment, different patterns are painted on the first fabric 100, the second fabric 200 and the third fabric 300 respectively.

Different curtain fabrics are designed into different styles of pattern shapes, so that the curtain fabric patterns displayed by the curtain structure in the visual field of a user can be quickly updated when the user switches the positions of the curtain fabrics of each layer, and the visual fatigue of the user is avoided.

In order to better explain the variable window curtain structure provided by the embodiment of the invention, a display schematic diagram of the variable window curtain structure shown by the embodiment of the invention is also shown, as shown in fig. 6, a third curtain cloth 300 is overlapped with a part of the first curtain cloth 100 and the second curtain cloth 200, so that the light transmission capability is poor.

In summary, the variable curtain structure provided by the invention receives the signal instruction received by the signal receiving device through the processor, and controls the position relationship of each curtain cloth in each track of the variable slide rail, so as to realize the updating of indoor and outdoor curtain cloth, and improve the visual experience of a user on the curtain structure; in addition, the adjustment of the blocking degree of the external light can be realized by controlling the stretching degree of each curtain cloth, so that the intensity of the indoor light is adjusted, and the adjustment of the light is not locally adjusted, so that the integration of the indoor light is ensured; finally, the curtain cloth structure can also adjust the indoor temperature by switching the position relation of the curtain cloth made of different materials.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

It will be understood that the invention is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the invention is limited only by the appended claims.

Claims

1. A variable curtain structure is characterized by comprising a first curtain cloth, a second curtain cloth, a third curtain cloth, a mounting guard plate, a variable slide rail, a signal receiving device and a processor; the variable slide rail comprises a first rail, a second rail, a third rail and six transfer rails, wherein transfer openings are formed in preset positions on the transfer rails; the upper end of the first curtain cloth is fixed on the first rail through a first pulley block, the upper end of the second curtain cloth is fixed on the second rail through a second pulley block, and the upper end of the third curtain cloth is fixed on the third rail through a third pulley block; the signal receiving device and the processor are arranged on one side of the variable sliding rail, the processor is respectively electrically connected with the signal receiving device, the first pulley block, the second pulley block and the third pulley block, and the processor is used for receiving a signal instruction received by the signal receiving device and controlling the first pulley block, the second pulley block and the third pulley block to move along each rail according to a preset rule according to the received signal instruction; the first curtain cloth, the second curtain cloth, the third curtain cloth, the variable slide rail, the signal receiving device and the processor are arranged in the installation protection plate, the surface of the first curtain cloth is coated with an anti-radiation coating, the second curtain cloth is made of a heat-conducting material, the surface of the third curtain cloth is coated with a heat-dissipation coating, the first curtain cloth is positioned on the outer layer, the second curtain cloth is positioned on the middle layer, and the third curtain cloth is positioned on the inner layer; the signal receiving device is used for transmitting a signal instruction to the processor after receiving the signal instruction sent by a user, and the processor controls each pulley block to move along each track according to a preset rule according to the signal instruction, so that the extension, contraction or position exchange of each curtain cloth is controlled.

2. The variable blind structure of claim 1, wherein the heat-dissipating coating composition comprises: ethyl acetate, graphene, aluminum oxide, epoxy resin, a stabilizer and a heat radiating agent.

3. The variable blind structure of claim 1 wherein said radiation protective coating composition comprises: talcum powder, glass powder, aluminum phosphate, titanium dioxide, mica powder and carbon nano tubes.

4. The variable curtain structure according to claim 1, wherein the thicknesses of the first cord fabric, the second cord fabric and the third cord fabric are 0.23-0.30cm, 0.18-0.23cm and 0.15-0.18cm in sequence.

5. The variable window covering structure of claim 1, wherein the first curtain, the second curtain and the third curtain are painted with different types of patterns respectively.

6. The variable blind structure of claim 1, wherein the size of each transfer opening is greater than the size of the individual pulleys of each pulley block.