CN220869185U - Window sunshade structure - Google Patents

Abstract

The application provides a window sunshade structure, which comprises a window frame inner frame surface, a window frame outer frame surface and a window rotating shaft glass panel arranged on the window frame inner frame surface, wherein the window rotating shaft glass panel comprises a first layer, a second layer and a third layer; the connecting rod comprises a fixing part and a telescopic part, wherein the fixing part is arranged on the inner frame surface of the window frame, and the telescopic part is arranged on the third layer of the glass panel. The window sunshade structure that above-mentioned provided is through the current defect to window sunshade structure, reduces the passing through of sunshine and set up the one deck insulating layer at the intermediate layer through application single face glass, and the integrated structure sets up like this and has both prevented the instability of traditional external sunshade structure and can improve window sunshade and heat-proof structure's performance and function, realizes more efficient sunshade and thermal-insulated effect.

Description

Window sunshade structure

Technical Field

The application relates to the technical field of sun-shading devices, in particular to a window sun-shading structure.

Background

In the building and window industries, window sunshade structures are designed to solve the problems of strong sunlight irradiation inside a building, indoor overheating and energy consumption reduction. The sunshade structure can effectively prevent sunlight from directly irradiating the room and provide comfortable indoor environment, and is also beneficial to reducing the energy consumption of air conditioning and heating. The traditional window sunshade structure usually adopts a shutter, a curtain and the like, and the sunshade methods can shield sunlight to a certain extent, but have limited effect. Modern window sunshade structures are more focused on the integration of technology and functionality to provide more efficient sunshade and thermal insulation.

At present, some innovative window sunshade structures are developed on the market, wherein the novel window sunshade structures comprise sunshade glass made of special materials, and some windows are made of special coatings or transparent heat insulation materials, so that heat conduction can be effectively isolated, indoor temperature is reduced, and air conditioning burden is reduced. Or the traditional sunshade structure such as a sun visor, a shutter and the like is arranged outside the window, or the connecting rods with adjustable heights are used for enabling some window connecting rods to be designed into a structure capable of being adjusted in a rotating mode, so that the height of the glass panel can be adjusted flexibly according to requirements.

However, the existing window sunshade structure still has some defects in practical application, and part of the sunshade structure is tedious, so that customization is required for different windows, and the cost is high. The traditional sun-shading methods such as a shutter, a curtain and the like are simple, but have limited effects, and cannot provide good heat insulation and sun-shading performance. The indoor climate may be affected by the external environment, reducing the thermal insulation performance of the window. Therefore, there is a need for a new window sunshade structure that overcomes the drawbacks of the prior art, provides a more efficient sunshade and heat insulation effect, and at the same time has flexible adjustment and stable air tightness.

Disclosure of utility model

In view of the above, there is a need to provide a window sunshade structure with good heat insulation effect to solve the above problems.

Embodiments of the present application provide a method comprising;

The window frame comprises a window frame inner frame surface and a window frame outer frame surface; the inner frame surface of the window frame is provided with a window rotating shaft;

The glass panel comprises a first layer, a second layer and a third layer, wherein the second layer is an interlayer of the first layer and the third layer, the third layer is arranged facing the window frame, and the first layer is connected with the window frame through a window rotating shaft;

The connecting rod comprises a fixing part and a telescopic part, wherein the fixing part is arranged on the inner frame surface of the window frame, and the telescopic part is arranged on the third layer of the glass panel.

In at least one embodiment of the present application, the fixed portion and the telescoping portion are of a telescoping rod construction.

In at least one embodiment of the present application, the inner frame surface of the window frame is provided with a groove, and the window frame can go deep into and be clamped in the groove.

In at least one embodiment of the present application, a sealing strip is disposed in the groove, so as to improve the tightness of the window.

In at least one embodiment of the present application, the window frame is provided with a first fixing hole, the fixing portion is provided with a second fixing hole corresponding to the first fixing hole, the screws respectively extend into and are fixed in the first fixing hole and the second fixing hole, and the fixing portion is sleeved and rotatably connected to the screws.

In at least one embodiment of the application, the first layer of the glass panel is a single-sided mirror for reducing sunlight ingress while ensuring transparency.

In at least one embodiment of the application, the second layer of the glass panel is a transparent thermal barrier coating for insulating the ingress of external temperature.

In at least one embodiment of the present application, the third layer of the glass panel is tempered glass for enhancing the strength of the glass panel.

In at least one embodiment of the application, the first layer, the second layer and the third layer are adhesively bonded.

In at least one embodiment of the present application, an airtight structure is disposed in the telescopic rod, and the airtight structure is disposed on an inner surface of the fixing rod, so as to stabilize the opening and closing of the glass panel.

The window sunshade structure that above-mentioned provided is through the current defect to window sunshade structure, reduces the passing through of sunshine and set up the one deck insulating layer at the intermediate layer through application single face glass, and the integrated structure sets up like this and has had both prevented the instability of traditional external sunshade structure and can improve window sunshade and heat insulation structure's performance and function, realizes more efficient sunshade and heat-proof effects, promotes indoor comfort level, energy saving and emission reduction, brings more benefits for the user.

Drawings

Fig. 1 is a perspective view of a window sunshade structure according to an embodiment of the present application.

Fig. 2 is an enlarged view of a portion of the glass panel and tie bar of fig. 1.

Description of the main reference signs

100. A window sunshade structure; 10. a window frame; 11. a window spindle; 12. a groove; 13. a sealing strip; 20. a glass panel; 21. a first layer; 22. a second layer; 23. a third layer; 30. a connecting rod; 31. a fixing part; 32. and a connecting part.

Detailed Description

Embodiments of the present application will now be described with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the application.

It is noted that when one component is considered to be "connected" to another component, it may be directly connected to the other component or intervening components may also be present. When an element is referred to as being "disposed" on another element, it can be directly on the other element or intervening elements may also be present. The terms "top," "bottom," "upper," "lower," "left," "right," "front," "rear," and the like are used herein for illustrative purposes only.

Some embodiments of the application are described in detail below with reference to the accompanying drawings. The following embodiments and features of the embodiments may be combined with each other without conflict.

Referring to fig. 1-2, an embodiment of the present application provides a window sunshade structure 100 comprising; the window frame 10 comprises an inner frame surface of the window frame 10 and an outer frame surface of the window frame 10; the inner frame surface of the window frame 10 is provided with a window rotating shaft 11; the glass panel 20 comprises a first layer 21, a second layer 22 and a third layer 23, wherein the second layer 22 is an interlayer between the first layer 21 and the third layer 23, the third layer 23 is arranged facing the window frame 10, and the first layer 21 is connected with the window frame 10 through the window rotating shaft 11; the connecting rod 30 further comprises a fixing portion 31 and a telescopic portion, wherein the fixing portion 31 is arranged on the inner frame surface of the window frame 10, and the telescopic portion is arranged on the third layer 23 of the glass panel 20.

Specifically, the window frame 10 is the base portion of the overall window shade structure 100, and includes two portions: the inner frame surface of the window frame 10 and the outer frame surface of the window frame 10. The inner frame surface of the window frame 10 is provided with a window rotation shaft 11 for realizing the opening and closing functions of the window. The glass panel 20 can rotate around the axis through the window rotating shaft 11, and the opening and closing actions are realized.

Further, the glass panel 20 is a shade portion of the window shade structure 100, which includes three layers: a first layer 21, a second layer 22 and a third layer 23. The second layer 22 is a layer sandwiched between the first layer 21 and the third layer 23, and the third layer 23 is disposed facing the window frame 10. The first layer 21 is connected to the window frame 10 through the window rotation shaft 11 so that it can move together with the opening and closing of the window frame 10 to achieve sun shading and sun shielding effects.

Still further, the connecting rod 30 is an assembly connecting the window frame 10 and the glass panel 20, and includes a fixing portion 31 and a telescopic portion. The fixing portion 31 is provided on the inner frame surface of the window frame 10, and serves to fix the window frame 10 and the connection rod 30. The telescoping portion is provided in the third layer 23 of the glass panel 20, which allows the glass panel 20 to telescope as the window is opened and closed, making the opening and closing action of the window more flexible and smooth.

Further, when the user needs to open or close the window, the window rotating shaft 11 on the inner frame surface of the window frame 10 is started by operating the opening button or the handle on the window frame 10. Rotation of the window spindle 11 will cause the first layer 21 of the glass panel 20 attached thereto to rotate together, thereby effecting opening or closing of the window. Meanwhile, the telescopic part on the third layer 23 of the glass panel 20 can be correspondingly telescopic and regulated according to the opening and closing state of the window, so that the stability of the glass panel 20 is ensured.

In summary, the window shade structure 100 can be widely applied to various buildings including houses, commercial buildings, office buildings, and the like. It is characterized in that it can achieve flexible opening and closing functions through the window rotating shaft 11, and simultaneously provides excellent sun-shading, heat-insulating and sealing effects through the multi-layer structure and airtight structure of the glass panel 20. In hot summer, the user can close the window to shield sunlight and external high temperature, so that indoor comfort is maintained; in warm spring and autumn, the user can open the window to enjoy natural ventilation and sunlight. In addition, the design of the grooves 12 on the inner frame surface of the window frame 10 and the application of the sealing strips 13 further improve the tightness of the window and prevent rainwater and wind from entering a room. In general, such a window shade structure 100 combines the functions of shading, insulating heat, sealing, ventilating, etc., and provides a more comfortable and convenient indoor environmental experience for the user.

In this embodiment, the fixing portion 31 and the telescopic portion in the window sunshade structure 100 are telescopic rod structures. In particular, the use of a telescoping rod structure allows for greater flexibility and adjustability of the window shade structure 100. The user can control the position of the glass panel 20 through the adjustment of the telescopic part according to the requirement, and the opening and closing of the window are realized, so that the indoor lighting and ventilation degrees are adjusted.

Further, when the user needs to open or close the window, the window rotating shaft 11 on the inner frame surface of the window frame 10 is started by operating the opening button or the handle on the window frame 10. Rotation of the window spindle 11 will cause the glass panel 20 attached thereto to rotate together, thereby effecting opening or closing of the window. Meanwhile, the telescopic part serves as a part of the connecting rod 30, and can be freely telescopic according to the operation of a user and the opening and closing state of the window, so that the stability and the reasonable opening and closing angle of the glass panel 20 are ensured.

In summary, in the residential building, the user can adjust the opening and closing degree of the window according to different seasons and weather conditions, so as to realize good ventilation and lighting effects and increase indoor ventilation and natural light utilization. In commercial buildings and office buildings, the window sunshade design of the telescopic rod structure can also provide more comfortable working environment for staff, so that the office has more adaptability and flexibility.

In this example, the window shade structure 100 has a groove 12 on the inner frame surface of the window frame 10, and the window frame 10 can be inserted into and engaged with the groove 12. In particular, the grooves 12 may be used to align and secure the position of the glass panel 20, ensuring a tighter fit of the glass panel 20 to the window frame 10 without loosening or disengagement. The stability between the connecting rod 30 and the glass panel 20 can be increased by providing the recess 12 on the inner frame surface of the window frame 10, so that the window structure is more firm and durable.

Further, when the window needs to be closed, the telescopic part of the glass panel 20 is retracted, so that the glass panel 20 is in a closed state. At this time, the window shaft 11 on the inner frame surface of the window frame 10 is activated to move the first layer 21 of the glass panel 20 along the groove 12 of the inner frame surface of the window frame 10. The presence of the grooves 12 allows the glass panel 20 to be precisely aligned, ensuring that the glass panel 20 is correctly and tightly engaged with the window frame 10, completing the closing action of the window.

In general, the arrangement of the grooves 12 can make the opening and closing of the window more stable and smooth, increase the tightness of the window, and effectively prevent external air flow, rainwater and the like from entering the room. In addition, the groove 12 structure also helps to improve the wind resistance of the window, and is particularly suitable for areas facing strong wind, sand wind and other climatic conditions. The window stability and tightness are improved, better sun shading, heat insulation and wind prevention effects are brought to users, and indoor comfort and safety are improved.

In the embodiment, the sealing strip 13 is disposed in the groove 12 in the window sunshade structure 100, so as to improve the tightness of the window. Specifically, the sealing strips 13 are arranged in the grooves 12, so that rainwater and external moisture can be effectively prevented from penetrating into the window, moisture leakage and seepage are prevented, and the indoor environment is ensured to be dry; and the gap between the inner frame surface of the window frame 10 and the glass panel 20 can be closed, so that the entry of external cold air is effectively isolated, and the heat insulation performance of the window is improved.

Further, when the window needs to be closed, the telescopic part of the glass panel 20 is retracted, so that the glass panel 20 is in a closed state. The groove 12 of the inner frame surface of the window frame 10 is tightly clamped with the glass panel 20, and the sealing strip 13 is arranged in the groove 12, so that an effective sealing waterproof structure is formed. The sealing strip 13 is made of soft and durable rubber or silica gel, has good elasticity and sealing performance, and can be tightly attached between the inner frame surface of the window frame 10 and the glass panel 20, so that the sealing state of the window is maintained.

In summary, the window sunshade structure 100 with the sealing strip 13 in the groove 12 can improve the tightness and heat preservation of the window, and create a more comfortable, safe and healthy indoor environment for the user.

In this example, the window shade structure 100 has a first fixing hole formed in the window frame 10, a second fixing hole corresponding to the first fixing hole formed in the fixing portion 31, and screws respectively inserted into and fixed to the first fixing hole and the second fixing hole, and the fixing portion 31 is sleeved and rotatably connected to the screws. Specifically, the first fixing hole formed in the window frame 10 and the second fixing hole formed in the fixing portion 31 are fixed by screws such that the connection rod 30 is firmly connected with the window frame 10. This ensures structural stability of the window, prevents the connecting portion 32 from loosening or falling off, and enhances durability and reliability of the window.

Further, one or more fixing holes, referred to as first fixing holes, are previously formed in the inner frame surface of the window frame 10. The fixing portion 31 of the connecting rod 30 is correspondingly provided with a second fixing hole corresponding to the first fixing hole. Then, the screws are respectively inserted into and fixed in the first fixing holes and the second fixing holes. The fixation of the screw firmly connects the connecting rod 30 to the window frame 10, ensuring a firm fixation between the connecting rod 30 and the window frame 10. Next, by loosening the connection of the fixing portion 31 with the screw, the fixing portion 31 of the connecting rod 30 can be turned on the screw, thereby achieving the rotational adjustment of the connecting rod 30 on the inner frame surface of the window frame 10.

In general, the fixing method is applicable to various types of windows, such as a family house, a commercial building, an office building, and public facilities. In these scenarios, the sun shading effect and the opening and closing angle of the window may need to be adjusted according to seasons, time or personal preference of the user. Through this kind of fixed mode, the user can adjust the position of connecting rod 30 as required for the window can realize sunshade and daylighting in a flexible way, ensures the fastness and the stability of structure simultaneously.

In practice the first layer 21 of the glass panel 20 in the window shade structure 100 is a single mirror for reducing sunlight ingress while ensuring transparency. In particular, a single-sided mirror is a specular material that is capable of reflecting light. By using a single mirror in the first layer 21 of the glass panel 20, sunlight can be reflected back out of the room, thereby reducing the amount of sunlight entering the room. This helps to reduce the temperature in the room, improve the comfort in the room, and effectively block intense sunlight.

Further, although the single-sided mirror may reflect light, its special design is such that the room still maintains a certain degree of transparency. This means that natural lighting is still available in the room, but not excessively exposed to direct sunlight, thus avoiding the problems of excessive brightness and glare.

In summary, the window shade structure 100 is suitable for use in situations where it is desirable to maintain indoor brightness, but where it is desirable to reduce direct sunlight exposure. For example, the balcony windows of offices, shops, houses, etc. of high-rise buildings. In these scenarios, the use of a single mirror as the first layer 21 of the glass panel 20 can provide good light for the room while reducing the temperature and glare in the room, providing a more comfortable indoor environment.

The second layer 22 of the glass panel 20 in the window shade structure 100 in this example is a transparent thermal barrier coating for insulating the entry of external temperatures. Specifically, the transparent heat-insulating coating is a special coating material having a heat-insulating function. By using a transparent thermal barrier coating on the second layer 22 of the glass panel 20, heat of an external high temperature can be effectively isolated from being transferred into the room. This helps to keep the temperature in the room stable, reduce the energy consumption of indoor air conditioning and heating, save energy sources, and improve indoor comfort.

Furthermore, the transparent heat-insulating coating has high transparency, can enable natural light to enter the room through the glass, keeps the room bright, avoids blocking the light by using a heat-insulating material with lower transparency, and provides a comfortable indoor environment.

In summary, such window shade structure 100 is suitable for use in situations where it is desirable to maintain stable indoor temperatures, particularly in areas where the climate is hot or cold. For example, offices, houses, hotels, etc. located in hot cities in high-temperature summer or in cold areas in cold winter. In these scenes, by using the glass panel 20 having the transparent heat-insulating coating layer, it is possible to effectively insulate the outside from high or low temperature while maintaining sufficient natural light, improve indoor comfort, and reduce energy consumption for air conditioning and heating.

In an embodiment, the third layer 23 of the glass panel 20 in the window sunshade structure 100 is tempered glass for enhancing the strength of the glass panel 20. Specifically, the toughened glass is a specially treated glass material, and the impact resistance and the bending resistance of the glass are enhanced by rapidly cooling the glass to form compressive stress on the surface of the glass and tensile force in the glass. In the window sunshade structure 100, the use of tempered glass as the third layer 23 can significantly improve the strength and durability of the glass panel 20, making it more durable and safer.

Further, when the window shade structure 100 is subjected to an external impact or force, the tempered glass of the third layer 23 of the glass panel 20 is subjected to pressure. As the surface of the toughened glass forms compressive stress, the toughened glass is more impact-resistant than common glass, and the possibility of breakage is reduced. Even when broken, the tempered glass fragments do not produce sharp edges, thereby reducing possible personnel injuries.

In summary, the window shade structure 100 using tempered glass as the third layer 23 is suitable for use in places where high requirements on the strength and safety of the window are required, especially in situations where it is required to prevent breakage of the window panel due to impact or unexpected events. Such as high-rise buildings, public places, children's activity areas, wind disaster frequent areas, etc.

In practice, the first layer 21, the second layer 22 and the third layer 23 are adhesively bonded in the window sunshade structure 100. Specifically, by adhesively bonding the first layer 21, the second layer 22 and the third layer 23 of glass panels 20, they will form an integral glass panel 20 unit after assembly. Such a glued joint can increase the overall strength of the glass panel 20, making it stronger and more durable.

Further, the glued joint can effectively tightly bond the different layers of the glass panel 20 together, avoiding possible loosening or voids between the layers. This helps to improve the durability of the window shade structure 100, enabling it to better cope with the effects of daily use and the external environment.

In summary, the window shade structure 100 using the glue joint is suitable for various places where it is required to reinforce the strength and durability of the window panel. Is particularly suitable for various application scenes such as high-rise buildings, public buildings, commercial offices, houses and the like. In these locations, window panels are often exposed to wind and rain attack and everyday use, by employing glued joints, it is possible to increase the robustness and durability of the window, provide longer service life, and promote the overall appearance of the building.

In this example, an airtight structure is disposed in the telescopic rod of the window sunshade structure 100, and the airtight structure is disposed on the inner surface of the fixed rod, so as to stabilize the opening and closing of the glass panel 20. Specifically, the airtight structure in the telescopic link can provide additional support and stability, ensure that the glass panel 20 can move smoothly when opened, and avoid unnecessary shaking or swaying, so that the use of the window sunshade structure 100 is more convenient and safe.

In summary, the design of the airtight structure makes the window sunshade structure 100 suitable for various application scenarios, especially in environments where it is necessary to maintain the tightness and sound insulation effect of the indoor space. Such window shade structure 100 may be employed in public places such as commercial buildings, offices, schools, hotels, and the like, as well as in residential homes, and the like. When the winter is cold, the airtight structure can effectively prevent indoor heat loss and reduce heating energy consumption; when the temperature is high in summer, the indoor air conditioner can isolate external heat and improve indoor air conditioning efficiency. In addition, such a window shade structure 100 is also suitable for large area windows, such as floor windows or large curtain walls, to ensure safe and stable movement of the large size glass panels 20, since the airtight structure can provide additional support and stability.

While the application has been described with respect to the above embodiments, it should be noted that modifications can be made by those skilled in the art without departing from the inventive concept, and these are all within the scope of the application.

Claims (7)

1. A window shade structure, comprising:

The window frame comprises a window frame inner frame surface and a window frame outer frame surface; the inner frame surface of the window frame is provided with a window rotating shaft;

The glass panel comprises a first layer, a second layer and a third layer, wherein the second layer is an interlayer of the first layer and the third layer, the third layer is arranged facing the window frame, and the first layer is connected with the window frame through a window rotating shaft;

The connecting rod comprises a fixing part and a telescopic part, the fixing part is arranged on the inner frame surface of the window frame, and the telescopic part is arranged on the third layer of the glass panel;

The first layer of the glass panel is a single-sided mirror and used for reducing sunlight incidence and guaranteeing transparency, and the second layer of the glass panel is a transparent heat-insulating coating and used for isolating external temperature.

2. The window shade structure of claim 1, wherein the fixed portion and the telescoping portion are telescoping rod structures.

3. The window shade structure of claim 2, wherein the inner frame surface of the window frame is provided with a groove, and the window frame can be inserted into and clamped in the groove.

4. A window shade structure according to claim 3, wherein a sealing strip is provided in the groove for improving the tightness of the window.

5. The window sunshade structure according to claim 1, wherein the window frame is provided with a first fixing hole, the fixing portion is provided with a second fixing hole corresponding to the first fixing hole, the screws respectively extend into and are fixed in the first fixing hole and the second fixing hole, and the fixing portion is sleeved and rotatably connected to the screws.

6. The window shade structure of claim 1, wherein the third layer of the glass panel is tempered glass for increasing the strength of the glass panel.

7. The window shade structure of claim 1, wherein the first layer, the second layer, and the third layer are adhesively bonded.