A roof decorative glass frame system integrating window cleaning machine access and wind load optimization.
By setting vertical functional gaps and steel structure support on the glass curtain wall facade, the problem of difficult window cleaning machine installation in traditional glass roof design has been solved, achieving convenient installation, reduced costs and improved safety, while maintaining the building's aesthetic appeal.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANGHAI BOTAO ARCHITECTURAL PLANNING & DESIGN CO LTD
- Filing Date
- 2025-08-11
- Publication Date
- 2026-07-03
Smart Images

Figure CN224451994U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of roof structure design for high-rise residential buildings, and in particular to a roof decorative glass frame system that integrates a window cleaning machine channel and wind load optimization. Background Technology
[0002] Currently, high-end residential buildings commonly adopt glass-framed roof designs to achieve a public building-like facade effect. However, traditional continuous enclosed glass roof designs have significant drawbacks: firstly, they hinder the normal extension of the window cleaning machine's cantilever, forcing the installation of the equipment at excessive heights, often necessitating the elimination of the window cleaning machine due to residential building height restrictions; secondly, adding external suspended platforms or other alternatives later on compromises the integrity of the building facade and incurs high annual maintenance costs. Existing solutions developed for public buildings such as office buildings and hotels, such as hydraulic lifting platforms, are difficult to directly adapt to residential buildings due to high costs and dimensional incompatibility. If residential projects completely eliminate window cleaning machines in pursuit of aesthetics, it will lead to difficulties in maintaining the exterior curtain wall and pose serious safety hazards.
[0003] Currently, there are two main improvement attempts in the industry: the rooftop openable window cleaning machine channel solution suffers from problems such as complex mechanical structure and high risk of water leakage; the decorative frame partially detachable panel solution suffers from drawbacks such as low efficiency of manual operation and damage to the integrity of the facade. Neither of these solutions has effectively resolved the contradiction between architectural aesthetic requirements and functional realization. Utility Model Content
[0004] The technical problem to be solved by this utility model is to provide a roof decorative glass frame system that integrates window cleaning machine channel and wind load optimization, which has the technical advantages of enabling convenient installation and maintenance of window cleaning machine while ensuring the integrity of building facade, and optimizing the distribution of structural wind load.
[0005] To solve the above-mentioned technical problems, this utility model adopts the following technical solution:
[0006] A roof decorative glass frame system integrating window cleaning machine access and wind load optimization includes a high-rise building body and a roof truss layer set on the top of the high-rise building body. The roof truss layer consists of at least one set of roof support structures and glass curtain wall facades set at the bottom of the corresponding roof support structures. The glass curtain wall facades are provided with a number of functional gaps for installing window cleaning machine cantilever arms, which are spaced left and right and arranged vertically.
[0007] Preferably, one functional gap is provided on every 2.0-2.5m of glass panel on the glass curtain wall facade.
[0008] Preferably, the functional gap is a vertically arranged rectangular gap, and its four edges are provided with a reinforced aluminum alloy frame.
[0009] Preferably, the gap width of the functional gap is 0.2-0.4m, and its total area accounts for ≤15% of the total area of the glass curtain wall facade.
[0010] Preferably, one functional gap is provided on every 2.0m glass panel on the glass curtain wall facade, and the gap width of the functional gap is 0.3m.
[0011] Preferably, the functional gap is detachably fitted with a bird-proof net through a reinforced aluminum alloy frame around it, and the mesh size of the bird-proof net is ≤20mm×20mm.
[0012] Preferably, the top of the functional gap extends upward to the location of the roof support structure and downward to the top ground of the high-rise building body or the location of the glass railing at the top of the high-rise building body.
[0013] Preferably, the roof truss layer further includes a glass railing arranged along the outer perimeter of the top of the high-rise building body, wherein:
[0014] The glass railing is installed at the bottom of the glass curtain wall facade or on the outer side of the glass curtain wall facade to enclose a terrace.
[0015] Preferably, the roof truss layer consists of two sets of roof support structures and a glass curtain wall facade disposed at the bottom of the corresponding roof support structures, wherein:
[0016] The two sets of roof support structures are asymmetrical and back-to-back on the top of the high-rise building, and each set of roof support structures is made of steel structure splicing.
[0017] More preferably, the roof support structure consists of a vertical support structure and a horizontal support structure, wherein:
[0018] The horizontal support structure is arranged in a U-shape with a horizontal tilt, and its two ends are integrally connected to the top of the vertical support structure. The bottom of each vertical support structure is fixedly installed on the top of the high-rise building body.
[0019] The present invention adopts the above technical solution and has the following technical effects compared with the prior art:
[0020] This utility model provides an integrated window cleaning machine access channel and a wind load-optimized roof decorative glass frame system. Through a structural design with pre-set functional gaps on the glass curtain wall facade, it maintains the integrity of the building facade while providing a dedicated installation channel for the window cleaning machine cantilever. At the same time, through optimized control of gap dimensions and distribution parameters, it effectively improves the distribution of structural wind loads. It has significant advantages in balancing architectural aesthetics and functional realization, reducing maintenance costs, and improving safety. In summary, this roof decorative glass frame system is the first to integrate the equipment access channel and decorative frame design, and is suitable for residential projects with public building-style glass facades. It innovatively solves the contradiction between window cleaning machine installation and architectural aesthetics through the roof decorative frame. Attached Figure Description
[0021] Figure 1 This is a schematic diagram of the roof truss layer in a roof decorative glass frame system that integrates window cleaning machine channel and wind load optimization according to this utility model.
[0022] Figure 2 This utility model Figure 1 The diagram shows the elevation structure of axes 1-21 in a roof decorative glass frame system that integrates window cleaning machine access and wind load optimization.
[0023] Figure 3 This utility model Figure 1 The diagram shows the elevation structure of axis 21-1 in a roof decorative glass frame system that integrates window cleaning machine access and wind load optimization.
[0024] Figure 4 This utility model Figure 1 The diagram shows the elevation structure of the NA axis in a roof decorative glass frame system that integrates window cleaning machine channels and optimizes wind load.
[0025] Figure 5 This utility model Figure 1 The diagram shows the elevation structure of the AN axis in a roof decorative glass frame system that integrates window cleaning machine channels and optimizes wind load.
[0026] Figure 6 This utility model Figure 1 The diagram shows a schematic elevation of axis 1 in a roof decorative glass frame system that integrates a window cleaning machine channel and optimizes wind load.
[0027] Figure 7 This utility model Figure 1 The diagram shows a two-axis elevation structure of a roof decorative glass frame system that integrates window cleaning machine channels and wind load optimization.
[0028] Figure 8 This utility model Figure 1The diagram shows the elevation structure of axes 18-21 in a roof decorative glass frame system that integrates window cleaning machine access and wind load optimization.
[0029] The accompanying figures are labeled as follows:
[0030] 100 - High-rise building body; 200 - Roof truss layer; 210 - Roof support structure; 211 - Vertical support structure; 212 - Horizontal support structure; 220 - Glass curtain wall facade; 221 - Glass panel; 222 - Functional gap; 223 - Reinforced aluminum alloy frame; 224 - Bird net; 230 - Glass fence. Detailed Implementation
[0031] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.
[0032] Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model.
[0033] In existing technologies, high-end residential buildings commonly employ continuous, enclosed glass roof structures to achieve a public building-like facade effect. While this design satisfies visual uniformity requirements, the completely enclosed structure hinders the normal extension of the window cleaning machine's cantilever arm. Traditional solutions utilize openable roof access channels or partially removable panels. The former significantly increases the risk of leakage due to its complex mechanical structure, while the latter requires frequent manual operation and compromises the facade's integrity. This dilemma has forced some projects to eliminate window cleaning machines, creating safety hazards for curtain wall maintenance, or compelling the use of ultra-high installation methods to overcome floor height restrictions, resulting in a substantial increase in construction costs.
[0034] To address the aforementioned issues and the pain point of enclosed glass roofs hindering equipment installation, this study first analyzed the spatial interference relationship between the cantilever trajectory of the window cleaning machine and the curtain wall structure. It was found that the cantilever extension only requires a localized passageway, rather than a complete opening and closing. The possibility of setting fixed passageways at intervals on the curtain wall facade was then considered. Wind tunnel tests were used to verify the impact of passageway width on wind pressure distribution, determining the critical value that satisfies both equipment access requirements and optimizes wind load. Finally, considering architectural aesthetics, the study explored the balance between passageway distribution density and visual continuity, resulting in an integrated design scheme for the equipment passageways and the building structure.
[0035] Therefore, as Figure 1 , Figure 2 , Figure 3 , Figure 4 and Figure 5As shown, this application proposes a roof decorative glass frame system that integrates window cleaning machine passage and wind load optimization. The system mainly includes a high-rise building body 100 and a roof truss layer 200 set on the top of the high-rise building body 100. The roof truss layer 200 consists of at least one set of roof support structure 210 and a glass curtain wall facade 220 set at the bottom of the corresponding roof support structure 210. The innovative solution is to have a number of functional gaps 222 for installing window cleaning machine cantilever arms that are pre-set at left and right intervals and arranged vertically on the glass curtain wall facade 220.
[0036] The roof support structure 210 refers to the main steel structure that supports the glass curtain wall facade 220. It can be implemented using a welded steel frame or a prefabricated truss structure, with its arrangement perpendicular to the functional gaps to ensure effective load transfer. The glass curtain wall facade 220 refers to a glass unit assembly consisting of several glass panels 221 that constitutes the building's external envelope. It can be implemented using insulated tempered glass assembled with a metal frame, forming a discontinuous surface structure through pre-set functional gaps.
[0037] Combination Figures 2 to 5 As shown, several functional gaps 222 can be set at intervals around the perimeter of the roof truss layer 200 to achieve 100% coverage of the building facade by the window cleaning machine, thereby improving the maintenance efficiency of the curtain wall. Furthermore, by setting up these functional gaps 222, the window cleaning machine can be placed directly on the roof of the high-rise building body 100 without having to be raised to the roof support structure 210, effectively reducing the installation cost of the window cleaning machine.
[0038] Specifically, the roof support structure 210 and the glass curtain wall facade 220 form a composite load-bearing system. The steel frame of the roof support structure 210 provides rigid fixing points for the glass curtain wall facade 220, and the functional gaps 222 spaced apart on the glass curtain wall facade 220 form a continuous channel in the vertical direction. In use, the cantilever of the window cleaning machine extends directly through the functional gaps 222 to clean the glass facade of the building. The lateral spacing of several functional gaps 222 allows the window cleaning machine to cover the entire curtain wall surface of the building, and the longitudinal cavity formed by the functional gaps 222 generates a diversion effect when encountering strong winds, which can effectively reduce the overall wind pressure value of the curtain wall surface.
[0039] Compared to existing technologies, traditional enclosed glass roofs require additional mechanical opening devices or temporary panel removal. This solution utilizes fixed functional gaps 222 to achieve permanent passageway functionality, eliminating the risk of failure in moving parts. Existing technologies often employ external wind deflectors for airflow guidance; this solution directly utilizes equipment passageways as airflow channels, achieving structural functional reuse. Conventional curtain wall maintenance access channels typically use independent inspection ports; this solution combines passageway distribution density with glass panel modularity to maintain the rhythmic division of the facade.
[0040] Through the above technical solution, this application enables the window cleaning machine to extend its cantilever directly from the roof layer without raising the supporting structure or compromising the integrity of the curtain wall, thus reducing the difficulty of equipment installation and maintenance costs. The air guiding channel formed by the functional gap 222 effectively disperses the peak wind pressure, reducing the risk of structural wind vibration damage. Moreover, the regular distribution of the functional gap 222 is coordinated with the building facade segmentation, maintaining visual integrity while meeting functional requirements.
[0041] In some of these embodiments, such as Figure 2 , Figure 3 , Figure 4 and Figure 5 As shown, this application further proposes to provide a functional gap 222 at regular intervals on the glass curtain wall facade 220, where each glass panel 221 is spaced at a certain distance. Specifically, one functional gap 222 is provided on the glass curtain wall facade 220 every 2.0-2.5m of glass panel 221, preferably one functional gap 222 is provided on every 2.0m of glass panel 221.
[0042] Among them, glass panel 221 refers to the standardized unit panel that constitutes the glass curtain wall facade. It can be produced and installed in the factory using a prefabrication method, and the modular design ensures the regularity of the facade splicing. The interval of a certain distance refers to the spacing range between two adjacent functional gaps. Specifically, it can be determined by matching the standard module of glass panel 221, so that the working radius of the window cleaning machine cantilever can cover the area between adjacent gaps.
[0043] Specifically, functional gaps 222 are regularly spaced throughout the glass curtain wall facade 220. The glass panel 221 areas between adjacent gaps are defined by standardized dimensions, ensuring that the window cleaning machine cantilever can extend to the building facade through the functional gaps 222 while also allowing the cantilever's rotation radius to cover the glass surface between adjacent gaps. The spacing of the functional gaps 222 is determined through structural mechanics calculations, forming a channel network that meets the equipment operation requirements while ensuring the overall load-bearing capacity of the curtain wall. The modular design of the glass panels 221 corresponds to the spacing of the functional gaps 222, creating a systematic solution for the production and installation of the glass curtain wall facade 220 and the layout of equipment channels.
[0044] In some of these embodiments, such as Figure 2 , Figure 3 , Figure 4 and Figure 5As shown, this application further proposes to provide vertically arranged rectangular gaps as functional gaps 222 on the glass curtain wall facade 220, and to provide reinforced aluminum alloy frames 223 around their four edges. The vertically arranged rectangular gaps refer to rectangular openings extending vertically, with their long sides parallel to the lifting trajectory of the window cleaning machine's cantilever, facilitating unobstructed passage of the equipment. The reinforced aluminum alloy frames 223 refer to a frame structure made of high-strength aluminum alloy profiles, specifically 6063-T5 aluminum alloy profiles with a wall thickness greater than or equal to 5 mm, assembled using corner brackets. The frame surface is treated with fluorocarbon coating to match the color of the glass curtain wall.
[0045] Specifically, this application further proposes to set functional gaps 222 on the glass curtain wall facade 220, with the gap width controlled within the range of 0.2-0.4m, and the total area of the gaps accounting for no more than 15% of the total area of the glass curtain wall facade. Preferably, the gap width of the functional gap 222 is 0.3m, which is the minimum safe value for the window cleaning machine arm to pass through, as verified by wind tunnel tests.
[0046] The gap width refers to the lateral dimension of the functional gap 222, which can be structurally supported by a reinforced aluminum alloy frame 223. This width range meets the equipment passage requirements while avoiding a decrease in the structural strength of the curtain wall due to excessively wide gaps. The total area ratio refers to the ratio of the cumulative area of all functional gaps 222 to the overall area of the glass curtain wall facade 220. This can be achieved through an intermittent arrangement. This ratio limit can effectively control the impact of gaps on the visual integrity of the building facade.
[0047] In some embodiments, this application further proposes that a functional gap 222 be provided on the glass curtain wall facade 220 at regular intervals between glass panels 221, and the gap width of the functional gap is a specific value. Specifically, one functional gap 222 is provided on the glass curtain wall facade 220 every 2.0m of glass panel 221, and the gap width of the functional gap 222 is 0.3m.
[0048] In some of these embodiments, such as Figure 6 , Figure 7 and Figure 8As shown, this application further proposes to install a detachable bird net 224 on the reinforced aluminum alloy frame 223 around the functional gap 222. The mesh size of the bird net does not exceed 20 mm by 20 mm. The bird net 224 refers to the protective structure installed at the opening of the functional gap, specifically woven from weather-resistant synthetic fiber material to ensure long-term use without aging in outdoor environments. The mesh size of no more than 20 mm by 20 mm refers to the maximum side length and width limit of a single mesh opening. Specifically, it can be formed by cross-weaving warp and weft threads to create evenly distributed square holes, which can both block common small birds from entering and avoid increasing wind resistance or affecting visual transparency due to excessively dense mesh.
[0049] Through the above technical solution, this application forms a controllable biological protective barrier at the functional gap 222, which not only avoids equipment malfunctions and hygiene problems caused by bird intrusion, but also ensures that the normal use of the window cleaning machine channel is not obstructed through the detachable design. The integrated installation of the bird net 224 and the reinforced aluminum alloy frame 223 maintains the visual continuity of the glass curtain wall facade, while balancing the protective effect and ventilation requirements by optimizing the mesh size.
[0050] In some of these embodiments, such as Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 6 , Figure 7 and Figure 8 As shown, this application further proposes to provide a functional gap 222 in the roof decorative glass frame system. The top of the functional gap 222 extends upward to the roof support structure 210 and downward to the top ground of the high-rise building or the top glass railing 230. Extending downward to the top ground means that the bottom of the gap is connected to the building's roof structural layer via a reinforced aluminum alloy frame 223. Extending to the glass railing means that the end of the gap is connected to the enclosure component via the reinforced aluminum alloy frame 223.
[0051] Specifically, the vertically continuous design of the functional gap 222 achieves effective load transfer through a rigid connection between the top and the load-bearing roof support structure 210. Simultaneously, the bottom extends to the ground or fence to form a continuous working space, allowing the window cleaning machine cantilever to extend directly from the building top to the operating area. The integration of the reinforced aluminum alloy frame 223 with the roof support structure 210 avoids the stability issues caused by the separation of traditional channels and structures. Furthermore, the downward extension to different end positions adapts to the diverse needs of the roof structure, ensuring both the reliability of equipment installation and maintaining the visual continuity of the facade components.
[0052] In some of these embodiments, such as Figure 6 , Figure 7 and Figure 8 As shown, this application further proposes to add a glass railing 230 to the roof truss layer 220, which is arranged along the outer periphery of the top of the high-rise building body 100. The glass railing 230 can be set at the bottom of the glass curtain wall facade 220 or at the outer side of the glass curtain wall facade 220 to enclose a terrace.
[0053] The glass railing 230 refers to a vertical protective structure made of transparent or semi-transparent glass, which can be achieved by combining tempered laminated glass with a metal frame. Its height meets building safety regulations. This structure weakens the visual presence of the enclosure components through the light transmittance of the material, thereby maintaining the continuity of the facade. The outer position refers to the area between the glass curtain wall facade 220 and the top edge of the building, which can be achieved by fixing the glass railing 230 to the cantilevered part of the roof structure through pre-embedded connectors.
[0054] In some of these embodiments, such as Figure 1 , Figure 2 , Figure 3 , Figure 4 and Figure 5 As shown, this application further proposes that the roof truss layer 200 is composed of two sets of roof support structures 210 and a glass curtain wall facade 220 set at the bottom of the corresponding roof support structures 210. The two sets of roof supports 210 are asymmetrical and set back to back on the top of the high-rise building body 100, and each set of roof support structures 210 is spliced from steel structures.
[0055] Specifically, the asymmetrical layout of the two sets of roof support structures 210 creates a mechanically balanced system at the top of the building, while their opposite orientation distributes the window cleaning machine channels in different directions, expanding the equipment's coverage area. The U-shaped inclined design of the horizontal support structure 212 guides airflow through the air duct, reducing the direct impact of wind pressure on the curtain wall facade. The bottom of the vertical support structure 211 is fixed to the top of the building, ensuring the stability of the overall structure.
[0056] Through the above technical solution, this application effectively balances the contradiction between architectural aesthetics and functional realization. The asymmetrical support system improves wind resistance while maintaining visual beauty. The gap area formed by the splicing of steel structures provides a structural foundation for the window cleaning machine channel, avoiding the problem of complicated mechanical structure in traditional solutions, and realizing the integrated integration of decorative frame and equipment channel.
[0057] Specifically, such as Figure 8 As shown, this application further proposes that the roof support structure 210 is composed of a vertical support structure 211 and a horizontal support structure 212. The horizontal support structure 212 is arranged in a U-shape with a horizontal inclination, and its two ends are respectively connected to the top of the vertical support structure 211. The bottom end of each vertical support structure 211 is fixedly installed on the top of the high-rise building body 100.
[0058] Among them, the vertical support structure 211 refers to the support members installed perpendicular to the top of the building, which can be implemented using H-beams or box-type steel columns, and is used to transfer the roof load to the main structure of the building. The horizontal support structure 212 refers to the support members extending in the horizontal direction, which can be implemented using H-beams or rectangular steel pipes bent into a U-shape. Its inclined arrangement can change the direction of wind load. The U-shaped horizontal inclined arrangement means that the horizontal members form an upward-opening curved shape in the horizontal plane, which can be achieved by segmented welding or integral cold bending, and the bending angle can be controlled within the range of 10-30°.
[0059] Through the above technical solutions, this application achieves a balance between the mechanical performance and functional requirements of the roof decoration frame support system. While ensuring unobstructed passage of the window cleaning machine cantilever, it disperses the wind load through structural morphology optimization, avoids fatigue damage to components caused by local stress concentration, and the streamlined shape of the U-shaped support structure 212 forms visual harmony with the glass curtain wall facade 220, maintaining the overall aesthetic performance of the building facade.
[0060] Combination Figures 1 to 8 As shown, the proposed solution maintains the integrity of the building facade and provides a dedicated installation channel for the window cleaning machine cantilever by pre-setting functional gaps 222 on the glass curtain wall facade 220. At the same time, the optimized control of gap size and distribution parameters effectively improves the distribution of structural wind loads. It has significant advantages in balancing architectural aesthetics and functional realization, reducing maintenance costs, and improving safety.
[0061] Finally, the following points should be noted: First, in the description of this application, it should be noted that, unless otherwise specified and limited, the terms "installation", "connection", and "linkage" should be interpreted broadly, and can be mechanical or electrical connections, or internal connections between two components, or direct connections. "Up", "down", "left", "right", etc. are only used to indicate relative positional relationships. When the absolute position of the described object changes, the relative positional relationship may change.
[0062] Secondly, the accompanying drawings of the embodiments disclosed in this utility model only involve the structures involved in the embodiments disclosed in this utility model. Other structures can refer to the general design. In the absence of conflict, the same embodiment and different embodiments of this utility model can be combined with each other.
[0063] Finally, the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.
Claims
1. A roof decorative glass frame system integrating a window cleaning machine channel and wind load optimization, comprising a high-rise building body (100) and a roof truss layer (200) arranged at the top of the high-rise building body (100), characterized in that, The roof truss layer (200) consists of at least one set of roof support structures (210) and a glass curtain wall facade (220) disposed at the bottom of the corresponding roof support structure (210). The glass curtain wall facade (220) is provided with a number of functional gaps (222) that are spaced apart on the left and right and arranged vertically for installing the cantilever of the window cleaning machine.
2. The integrated glazing channel and wind load optimized roof trim glass framing system of claim 1, wherein, On the glass curtain wall facade (220), one functional gap (222) is provided for every 2.0-2.5m glass panel (221).
3. The integrated glazing channel and wind load optimized roof trim glass framing system of claim 1, wherein, The functional gap (222) is a vertically arranged rectangular gap, and its four edges are all provided with reinforced aluminum alloy frames (223).
4. The integrated glazing channel and wind load optimized roof trim glass construction system of claim 1, wherein, The gap width of the functional gap (222) is 0.2-0.4m, and its total area accounts for ≤15% of the total area of the glass curtain wall facade (220).
5. The integrated glazing channel and wind load optimized roof trim glass construction system of claim 1, wherein, On the glass curtain wall facade (220), a functional gap (222) is provided for every 2.0m glass panel (221), and the gap width of the functional gap (222) is 0.3m.
6. The integrated glazing channel and wind load optimized roof trim glass construction system of claim 1, wherein, The functional gap (222) is detachably fitted with a bird net (224) through a reinforced aluminum alloy frame (223) around it, the mesh size of the bird net (224) being ≤20mm×20mm.
7. The integrated window cleaning machine channel and wind load optimized roof decorative glass frame system according to claim 1, characterized in that, The top of the functional gap (222) extends upward to the location of the roof support structure (210) and downward to the top ground of the high-rise building body (100) or the location of the glass railing (230) at the top of the high-rise building body (100).
8. The integrated glazing channel and wind load optimized roof trim glass construction system of claim 1, wherein, The roof truss layer (200) also includes a glass railing (230) arranged along the outer perimeter of the top of the high-rise building body (100), wherein: The glass railing (230) is located at the bottom of the glass curtain wall facade (220) or on the outer side of the glass curtain wall facade (220) to enclose a terrace.
9. The integrated glazing channel and wind load optimized roof trim glass construction system of claim 1, wherein, The roof truss layer (200) consists of two sets of roof support structures (210) and a glass curtain wall facade (220) located at the bottom of the corresponding roof support structure (210), wherein: The two sets of roof support structures (210) are asymmetrically and back-to-back on the top of the high-rise building body (100), and each set of roof support structures (210) is made of steel structure splicing.
10. The integrated glazing channel and wind load optimized roof trim glass construction system of claim 9, wherein, The roof support structure (210) consists of a vertical support structure (211) and a horizontal support structure (212), wherein: The horizontal support structure (212) is arranged in a U-shape with a horizontal tilt, and its two ends are respectively connected to the top of the vertical support structure (211). The bottom of each vertical support structure (211) is fixedly installed on the top of the high-rise building body (100).