Energy-saving fire rescue window system with real stone paint

By using a double-layer structure design with windows that open inwards and outwards, and cement fiberboard coated with real stone paint, the problem of rapid removal of fire rescue windows in real stone paint curtain walls was solved, achieving a balance between the building's aesthetics and energy-saving effects.

CN224396340UActive Publication Date: 2026-06-23SUZHOU GOLD MANTIS CURTAIN WALL CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SUZHOU GOLD MANTIS CURTAIN WALL CO LTD
Filing Date
2025-06-05
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

In existing technologies, it is difficult to quickly remove real stone paint materials from curtain wall fire rescue window systems without damaging the aesthetics of the building facade, which poses a technical challenge to the design of rescue windows.

Method used

The design features a double-layer structure with an inner glass window and an outer opening window. Cement fiberboard is sprayed with real stone paint. In the outer opening window, galvanized iron sheet and cement fiberboard form a cavity filled with insulating rock wool. The aluminum alloy window frame and window sash are hinged by stainless steel hinges, and hardware locks enable quick opening. The inner glass window is fixed by an aluminum alloy base.

Benefits of technology

It enables rapid opening of rescue access in emergency situations without compromising the aesthetics of the building's facade, while also enhancing the building's thermal insulation and lighting and ventilation requirements, thus conforming to the concept of green building.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224396340U_ABST
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Abstract

The utility model discloses a kind of real stone paint energy-saving fire rescue window systems that can be enabled, it is related to curtain wall fire rescue window technical field, include building structure, inner glass window and outer opening window;Building structure is preset with opening, and inner glass window and outer opening window are all installed and fixed in the opening of building structure, and inner glass window is located at the inboard of outer opening window;Outer opening window includes aluminum alloy window frame, aluminum alloy window sash and cement fiberboard;The opening inboard of building structure is provided with a plurality of window frame supports, and aluminum alloy window frame is fixed in the opening of building structure by a plurality of window frame supports;The scheme is by spraying real stone paint on the outside of cement fiberboard, when encountering emergency rescue situation, rescue personnel can directly remove or break cement fiberboard, break through the limitation that traditional real stone paint is difficult to handle, open rescue passage quickly, guarantee rescue timeliness, while not damaging the real stone paint decoration layer of other parts of building facade, maintain building facade aesthetic property.
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Description

Technical Field

[0001] This utility model relates to an energy-saving fire rescue window system that can utilize real stone paint, belonging to the technical field of curtain wall fire rescue windows. Background Technology

[0002] For all types of large commercial buildings, fire rescue windows must be installed in strict accordance with fire safety regulations to ensure that outdoor rescue personnel can quickly enter and reach the rescue site in case of sudden emergencies and carry out effective rescue.

[0003] Stone-like paint, as a common exterior wall decoration material, has been widely used for the beautification and protection of masonry and concrete walls. However, in the design and application of fire rescue windows, traditional panel materials such as glass and aluminum plates can usually be broken or removed for rapid rescue. Due to its unique physical properties, the stone-like paint layer on the surface of masonry and concrete walls is difficult to break or remove using existing technologies. This directly leads to a technical challenge when installing fire rescue windows in curtain wall systems. Specifically, how to reasonably and effectively solve the problem of using stone-like paint materials in curtain wall rescue window systems without compromising the aesthetics of the building facade has become a key technical difficulty that urgently needs to be solved in the industry. Utility Model Content

[0004] The purpose of this utility model is to overcome the shortcomings of the existing technology and provide an energy-saving fire rescue window system that can be activated with real stone paint.

[0005] To achieve the above objectives, the technical solution adopted by this utility model is: an energy-saving fire rescue window system with real stone paint, comprising a building structure, an inner glass window and an outer opening window; the building structure has a pre-set opening, and the inner glass window and the outer opening window are both installed and fixed in the opening of the building structure, with the inner glass window located inside the outer opening window;

[0006] The outward-opening window comprises an aluminum alloy window frame, an aluminum alloy window sash, and a cement fiberboard. Multiple window frame supports are provided around the inner side of the opening in the building structure, and the aluminum alloy window frame is fixed within the opening via these supports. The aluminum alloy window sash is hinged to the aluminum alloy window frame, and a hardware lock is provided on the opening side of the aluminum alloy window sash, allowing it to be locked or unlocked from the aluminum alloy window frame via the hardware lock. The cement fiberboard is connected and fixed to the outer side of the aluminum alloy window sash, and the outer side of the cement fiberboard is coated with real stone paint, with the outer surface of the cement fiberboard flush with the exterior wall of the building structure.

[0007] Preferably, the inner glass window includes a glass panel and an aluminum alloy base. The aluminum alloy base is shaped like a "Z" and is fixed to the inner wall of the opening in the building structure. The edge of the glass panel is inserted and fixed in the "Z" shaped groove of the aluminum alloy base.

[0008] Preferably, an aluminum alloy pressure line is provided on the indoor side of the glass panel. The aluminum alloy pressure line is arranged around the inner wall of the opening in the building structure, and the aluminum alloy pressure line presses the glass panel tightly from the inside.

[0009] Preferably, a galvanized iron sheet is fixedly installed on the inner side of the aluminum alloy window sash, and a cavity is formed between the galvanized iron sheet and the cement fiberboard, and thermal insulation rock wool is installed in the cavity.

[0010] Preferably, both the aluminum alloy window frame and the aluminum alloy window sash are assembled from aluminum alloy profiles. The left and right sides of the cement fiberboard are fixed to the frame profiles of the aluminum alloy window sash with self-tapping screws. A connecting angle steel is fixed in the middle of the aluminum alloy window sash, and the middle of the cement fiberboard is fixed to the connecting angle steel with self-tapping screws.

[0011] Preferably, a stainless steel hinge is provided between the aluminum alloy window frame and the aluminum alloy window sash. The stainless steel hinge is L-shaped, and the aluminum alloy window sash is hinged to the aluminum alloy window frame through the stainless steel hinge.

[0012] Preferably, the window frame support is Z-shaped and is fixed to the opening in the building structure by anchor bolts.

[0013] Due to the application of the above technical solution, this utility model has the following advantages compared with the prior art:

[0014] 1. This utility model sprays real stone paint onto the outside of cement fiberboard. In case of emergency rescue, rescuers can directly remove or break the cement fiberboard, overcoming the limitations of traditional real stone paint, which is difficult to handle, quickly opening rescue channels, ensuring the timeliness of rescue, and at the same time not damaging the real stone paint decorative layer on other parts of the building facade, maintaining the aesthetics of the building facade.

[0015] 2. The double-layer structure design of internal glass windows and external opening windows not only ensures the building's lighting and ventilation needs, but also enhances the building's thermal insulation performance by filling the cavity formed by the galvanized iron sheet and cement fiberboard in the external opening windows with insulating rock wool, thus achieving energy-saving effects and making it more in line with the green building concept of energy conservation and emission reduction. Attached Figure Description

[0016] The technical solution of this utility model will be further described below with reference to the accompanying drawings:

[0017] Appendix Figure 1 This is a cross-sectional view of an energy-saving fire rescue window system with activated real stone paint as described in this utility model.

[0018] Appendix Figure 2 For the appendix Figure 1 Enlarged view of point A in the middle;

[0019] Appendix Figure 3 For the appendix Figure 1 Enlarged view of point B in the middle;

[0020] Appendix Figure 4 For the appendix Figure 1 A magnified view of point C in the middle.

[0021] In the diagram: 1. Building structure; 11. Opening; 111. Window frame support; 2. Interior glass window; 21. Glass panel; 22. Aluminum alloy base; 3. Outward opening window; 31. Aluminum alloy window frame; 32. Aluminum alloy window sash; 321. Galvanized iron sheet; 322. Connecting angle steel; 33. Cement fiberboard; 4. Hardware locks; 5. Stone paint; 6. Aluminum alloy trim; 7. Thermal insulation rock wool; 8. Stainless steel hinge; 9. Anchor bolt. Detailed Implementation

[0022] The present invention will now be described in further detail with reference to the accompanying drawings and specific embodiments.

[0023] As attached Figure 1-4 As shown, the present invention provides an energy-saving fire rescue window system with real stone paint, comprising a building structure 1, an inner glass window 2, and an outer opening window 3; the building structure 1 has a pre-set opening 11, and the inner glass window 2 and the outer opening window 3 are both installed and fixed in the opening 11 of the building structure 1, with the inner glass window 2 located inside the outer opening window 3.

[0024] The outward-opening window 3 includes an aluminum alloy window frame 31, an aluminum alloy window sash 32, and a cement fiberboard 33. In this embodiment, both the aluminum alloy window frame 31 and the aluminum alloy window sash 32 are assembled from aluminum alloy profiles. The aluminum alloy window frame 31 and the aluminum alloy window sash 32 are assembled in the factory, and EPDM rubber strips are inserted into the corresponding grooves of the aluminum alloy profiles to ensure airtightness and watertightness. The cement fiberboard 33 has a water absorption rate of less than 20% and a density of more than 2g / cm³. 3 High-density cement fiberboard.

[0025] Multiple window frame supports 111 are provided around the inner side of the opening 11 of the building structure 1. In this embodiment, the window frame supports 111 are made of galvanized steel. The window frame supports 111 are Z-shaped and fixed in the opening 11 of the building structure 1 by anchor bolts 9. The aluminum alloy window frame 31 is fixed in the opening 11 of the building structure 1 by multiple window frame supports 111 to ensure the installation stability of the aluminum alloy window frame 31. The aluminum alloy window frame 31 and the window frame supports 111 can be fixed with long screws to complete the installation of the aluminum alloy window frame 31.

[0026] The aluminum alloy window sash 32 is hinged to the aluminum alloy window frame 31. Specifically, a stainless steel hinge 8 is provided between the aluminum alloy window frame 31 and the aluminum alloy window sash 32. The stainless steel hinge 8 is L-shaped, and the aluminum alloy window sash 32 is hinged to the aluminum alloy window frame 31 through the stainless steel hinge 8. A hardware lock 4 is provided on the opening side of the aluminum alloy window sash 32, and the opening side of the aluminum alloy window sash 32 is locked or unlocked to the aluminum alloy window frame 31 through the hardware lock 4.

[0027] In this embodiment, the hardware lock 4 adopts a two-point lock commonly used in the art. To briefly explain, the two-point lock consists of a lock base, a locking point, and a handle. The lock base is installed at the corresponding position on the aluminum alloy window frame 31. According to the position of the lock hole on the lock base, the locking point is installed at a suitable position on the aluminum alloy window sash 32. During installation, holes are first drilled on the window frame and window sash, and the lock base and locking point are firmly fixed with screws to ensure that the holes are accurately aligned. Then, the handle is installed. The handle is connected to the locking point through a transmission rod. After installation, it is adjusted to ensure that when the handle is rotated, the locking point can be smoothly inserted into or disengaged from the lock base to achieve locking and unlocking. Of course, multi-point locks, bolt locks, and other hardware locks commonly used in the art can also be used.

[0028] The cement fiberboard 33 is connected and fixed to the outside of the aluminum alloy window sash 32. Specifically, the left and right sides of the cement fiberboard 33 are fixed to the frame profile of the aluminum alloy window sash 32 by self-tapping screws. A connecting angle steel 322 is fixedly installed in the middle of the aluminum alloy window sash 32, and the middle of the cement fiberboard 33 is fixed to the connecting angle steel 322 by self-tapping screws to ensure the stable installation of the cement fiberboard 33 on all four sides and in the middle, thereby improving the connection stability.

[0029] The outer side of the cement fiberboard 33 is sprayed with real stone paint 5, so that the appearance of the outward-opening window 3 is consistent with the overall style of the building facade. This effectively solves the compatibility problem between the solid panel of the rescue window and the wall of real stone paint 5, significantly reduces the risk of real stone paint 5 falling off, thereby improving the safety performance of the rescue window and extending the overall service life of the building. At the same time, the outer side of the cement fiberboard 33 is flush with the outer wall of the building structure 1, which can further ensure the uniformity of the building appearance.

[0030] This utility model uses an aluminum alloy window system as the basis for the stone paint 5 wall rescue window panel system, providing a stable and reliable installation foundation for the stone paint 5 panel while ensuring that fire rescue work can be carried out smoothly in emergency situations.

[0031] Furthermore, a galvanized iron sheet 321 is fixedly installed on the inner side of the aluminum alloy window sash 32, and a cavity is formed between the galvanized iron sheet 321 and the cement fiberboard 33. Insulating rock wool 7 is installed in the cavity to enhance the thermal insulation performance of the outward-opening window 3.

[0032] The inner glass window 2 includes a glass panel 21 and an aluminum alloy base 22. The aluminum alloy base 22 is shaped like a "Z" and can be fixed to the inner wall of the opening 11 of the building structure 1 by means of screws, adhesives, etc. The edge of the glass panel 21 is inserted and fixed in the "Z" shaped groove of the aluminum alloy base 22 to complete the installation of the inner glass window 2. This not only meets the requirement of being breakable for fire rescue but also achieves the visual requirement of aesthetics on the interior side. At the same time, it provides a second waterproof barrier for the entire real stone paint 5 rescue window system and further improves the thermal performance of the building.

[0033] Furthermore, an aluminum alloy pressure wire 6 is provided on the indoor side of the glass panel 21. The aluminum alloy pressure wire 6 is provided around the inner wall of the opening 11 of the building structure 1. The aluminum alloy pressure wire 6 presses the glass panel 21 from the inside to ensure that the glass panel 21 is securely installed and to prevent it from loosening or falling off.

[0034] The above are merely specific application examples of this utility model and do not constitute any limitation on the scope of protection of this utility model; all technical solutions formed by equivalent transformation or equivalent substitution fall within the scope of protection of this utility model.

Claims

1. An energy efficient fire rescue window system activatable with a real stone paint (5), characterized in that: It includes a building structure (1), an inner glass window (2) and an outer opening window (3); the building structure (1) has a pre-set opening (11), the inner glass window (2) and the outer opening window (3) are both installed and fixed in the opening (11) of the building structure (1), and the inner glass window (2) is located inside the outer opening window (3); The outward-opening window (3) includes an aluminum alloy window frame (31), an aluminum alloy window sash (32), and a cement fiberboard (33); a plurality of window frame supports (111) are provided around the inner side of the opening (11) of the building structure (1), and the aluminum alloy window frame (31) is fixed in the opening (11) of the building structure (1) by the plurality of window frame supports (111); the aluminum alloy window sash (32) is hinged to the aluminum alloy window frame (31), and a hardware lock (4) is provided on the opening side of the aluminum alloy window sash (32), and the opening side of the aluminum alloy window sash (32) is locked or unlocked to the aluminum alloy window frame (31) by the hardware lock (4); the cement fiberboard (33) is connected and fixed to the outside of the aluminum alloy window sash (32), and the outside of the cement fiberboard (33) is sprayed with real stone paint (5), and the outer side of the cement fiberboard (33) is flush with the outer wall of the building structure (1).

2. An energy efficient fire rescue window system with an activatable real stone paint (5) according to claim 1, characterized in that: The inner glass window (2) includes a glass panel (21) and an aluminum alloy base (22). The aluminum alloy base (22) is shaped like a zigzag and is fixed to the inner wall of the opening (11) of the building structure (1). The edge of the glass panel (21) is inserted and fixed in the zigzag groove of the aluminum alloy base (22).

3. An energy efficient fire rescue window system with an activatable real stone paint (5) according to claim 2, characterized in that: An aluminum alloy pressure line (6) is provided on the indoor side of the glass panel (21). The aluminum alloy pressure line (6) is arranged around the inner wall of the opening (11) of the building structure (1). The aluminum alloy pressure line (6) presses the glass panel (21) tightly from the inside.

4. The energy-saving fire rescue window system with activated real stone paint (5) as described in claim 1, characterized in that: A galvanized iron sheet (321) is fixedly installed on the inner side of the aluminum alloy window sash (32), and a cavity is formed between the galvanized iron sheet (321) and the cement fiberboard (33), and thermal insulation rock wool (7) is installed in the cavity.

5. The energy-saving fire rescue window system with activated real stone paint (5) according to claim 1, characterized in that: The aluminum alloy window frame (31) and aluminum alloy window sash (32) are both made of aluminum alloy profiles. The left and right sides of the cement fiberboard (33) are fixed to the frame profiles of the aluminum alloy window sash (32) by self-tapping screws. A connecting angle steel (322) is fixed in the middle of the aluminum alloy window sash (32). The middle of the cement fiberboard (33) is fixed to the connecting angle steel (322) by self-tapping screws.

6. The energy-saving fire rescue window system with activated real stone paint (5) according to claim 1, characterized in that: A stainless steel hinge (8) is provided between the aluminum alloy window frame (31) and the aluminum alloy window sash (32). The stainless steel hinge (8) is L-shaped, and the aluminum alloy window sash (32) is hinged to the aluminum alloy window frame (31) through the stainless steel hinge (8).

7. The energy-saving fire rescue window system with activated real stone paint (5) according to claim 1, characterized in that: The window frame support (111) is Z-shaped and is fixed in the opening (11) of the building structure (1) by anchor bolts (9).