Vertical strong and weak electricity well structure of high-rise building

By adopting a vertical strong and weak current shaft structure in high-rise buildings, and using partitions and fireproof partitions to isolate the strong current chamber from the weak current chamber, the problems of large area occupation and interference of strong and weak current shafts are solved, achieving efficient space utilization and equipment isolation.

CN224379329UActive Publication Date: 2026-06-19BEIJING CCI ARCHITECTURAL DESIGN

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BEIJING CCI ARCHITECTURAL DESIGN
Filing Date
2025-06-19
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In existing high-rise buildings, power supply shafts and low-voltage supply shafts are often located on the same floor, which leads to equipment interference and occupies a large area, affecting space utilization.

Method used

A vertical strong and weak current well structure is adopted. The space inside the well shaft is divided into alternating strong current chambers and weak current chambers by a partition plate, and fireproof partitions are used for isolation to form a cable tray installation area for cable routing.

Benefits of technology

It effectively isolates electrical signal interference between high-voltage and low-voltage equipment, reduces the area occupied by electrical shafts, improves space utilization, and enhances building comfort and economic benefits.

✦ Generated by Eureka AI based on patent content.

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Abstract

This application relates to a vertical electrical and communication shaft structure for high-rise buildings, comprising: a shaft shaft and two or more partition plates; the two or more partition plates are horizontally placed inside the shaft shaft and arranged sequentially along the length of the shaft shaft, suitable for dividing the cavity inside the shaft shaft into multiple high-voltage chambers suitable for placing high-voltage equipment and multiple low-voltage chambers suitable for placing low-voltage equipment, with the high-voltage and low-voltage chambers arranged alternately in sequence; each partition plate has a preset distance between it and the opposite side walls of the shaft shaft to form a cable tray installation area; each high-voltage chamber is provided with a first fireproof partition plate, and each low-voltage chamber is provided with a second fireproof partition plate, with the first and second fireproof partition plates connected to each partition plate located at opposite ends of the partition plate. The vertical layout of the high-voltage and low-voltage chambers in this application can effectively reduce the area occupied by the electrical shaft within the building, freeing up more building space and enhancing comfort.
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Description

Technical Field

[0001] This application relates to the field of architectural design technology, and in particular to a vertical electrical and communication shaft structure for high-rise buildings. Background Technology

[0002] Electrical shafts, also known as cable shafts, are reserved channels for laying cables and wires. High-rise buildings require electrical circuits, and electrical shafts are the shafts installed inside the building to carry these pipelines and deliver the cables to each household and unit. Electrical shafts are divided into high-voltage (power) shafts and low-voltage (data) shafts. High-voltage shafts are used for lighting and power, while low-voltage shafts are mainly used for communication, monitoring, and data transmission. In current electrical shaft structural designs, high-voltage and low-voltage shafts are often located on the same floor. However, to avoid interference between high-voltage and low-voltage equipment, these shafts need to be separated, so that high-voltage and low-voltage equipment operate in two different spaces on the same floor. This horizontal layout increases the area occupied by electrical shafts within the building, reducing office, commercial, or residential space, resulting in low space utilization within the building. Summary of the Invention

[0003] In view of this, this application proposes a vertical electrical and communication shaft structure for high-rise buildings.

[0004] According to one aspect of this application, a vertical electrical and weak current shaft structure for a high-rise building is provided, comprising: an electrical shaft cylinder and two or more partition plates;

[0005] Two or more partition plates are placed horizontally inside the electric well shaft and arranged sequentially along the length of the electric well shaft. This is suitable for dividing the cavity inside the electric well shaft into multiple high-voltage chambers suitable for placing high-voltage equipment and multiple low-voltage chambers suitable for placing low-voltage equipment, with the high-voltage chambers and low-voltage chambers arranged alternately in sequence.

[0006] Each partition plate is provided with a preset distance between its opposite side walls and the electrical well shaft to form a cable tray installation area;

[0007] Each high-voltage chamber is equipped with a first fireproof partition, which is perpendicular to and fixedly connected to the upper and lower partitions of the high-voltage chamber.

[0008] Each low-voltage electrical chamber is equipped with a second fireproof partition, which is perpendicular to and fixedly connected to the upper and lower partitions of the low-voltage electrical chamber.

[0009] The first and second fireproof partitions connected to each partition are located at opposite ends of the partition.

[0010] In one possible implementation, the distance between each partition is the same.

[0011] In one possible implementation, each partition plate is fixed to the opposite sidewall of the electric well shaft on the side with the opening.

[0012] In one possible implementation, the preset distance is 1 / 10 of the internal width of the electric well shaft.

[0013] In one possible implementation, the upper and lower sides of the first fireproof partition and the upper and lower sides of the second fireproof partition are both fixedly connected to the partition plate by fixing pipe clamps.

[0014] In one possible implementation, adhesive layers are provided between the upper and lower sides of the first fireproof partition and the partition board; adhesive layers are provided between the upper and lower sides of the second fireproof partition and the partition board.

[0015] In one possible implementation, both the first and second fireproof partitions are made of ALC wall panels.

[0016] In one possible implementation, both the first fireproof partition and the second fireproof partition are provided with through holes.

[0017] Beneficial Effects: The electrical shaft vertically penetrates the building, forming an internal cavity that can accommodate high-voltage and low-voltage equipment, as well as cabling for each floor. Multiple partitions are horizontally placed within the shaft's cavities, arranged sequentially along its length, thus dividing the space into multiple layers of high-voltage and low-voltage chambers, arranged alternately. The partitions provide equipment support while simultaneously separating adjacent high-voltage and low-voltage chambers, effectively isolating them and preventing signal interference. This also improves the uniformity of the high-voltage and low-voltage chambers within the shaft, facilitating power supply to each floor of the building. The vertical layout of the high-voltage and low-voltage chambers in this application meets the functional requirements of conventional electrical shafts while effectively reducing their footprint within the building, freeing up more building space and enhancing comfort.

[0018] Other features and aspects of this application will become clear from the following detailed description of exemplary embodiments with reference to the accompanying drawings. Attached Figure Description

[0019] The accompanying drawings, which are included in and form part of this specification, illustrate exemplary embodiments, features, and aspects of this application together with the specification and serve to explain the principles of this application.

[0020] Figure 1 This is a front view of a vertical electrical and communication shaft structure for a high-rise building according to an embodiment of this application.

[0021] Figure 2This is a front view of a vertical electrical and communication shaft structure for a high-rise building according to an embodiment of this application.

[0022] Figure 3 This diagram shows the main structure of a vertical electrical and communication shaft structure for a high-rise building according to an embodiment of this application.

[0023] Figure 4 This diagram shows the main structure of a vertical electrical and communication shaft structure for a high-rise building according to an embodiment of this application.

[0024] Figure 5 A layout diagram of the high-voltage chamber according to an embodiment of this application is shown;

[0025] Figure 6 A layout diagram of the low-voltage chamber according to an embodiment of this application is shown;

[0026] Figure 7 This diagram shows the main structure of the ALC wall panel according to an embodiment of this application.

[0027] Figure 8 This diagram illustrates the connection structure of the ALC wall panel according to an embodiment of this application.

[0028] Figure 9 Show Figure 8 A magnified view of a portion of the image;

[0029] Figure 10 This diagram illustrates the connection structure of the ALC wall panel according to an embodiment of this application.

[0030] Figure 11 Show Figure 10 A magnified view of a portion of the image;

[0031] Figure 12 A top view of a fireproof partition wall according to a first embodiment of this application is shown;

[0032] Figure 13 A top view of a fireproof partition wall according to a second embodiment of this application is shown;

[0033] Figure 14 The layout diagram of the existing strong and weak current chambers is shown. Detailed Implementation

[0034] Various exemplary embodiments, features, and aspects of this application will now be described in detail with reference to the accompanying drawings. The same reference numerals in the drawings denote elements that have the same or similar functions. Although various aspects of the embodiments are shown in the drawings, they are not necessarily drawn to scale unless specifically indicated otherwise.

[0035] It should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", and "circumferential" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model or simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.

[0036] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this utility model, "a plurality of" means two or more, unless otherwise explicitly specified.

[0037] The term “exemplary” as used herein means “serving as an example, embodiment, or illustration.” Any embodiment illustrated herein as “exemplary” is not necessarily to be construed as superior to or better than other embodiments.

[0038] Furthermore, to better illustrate this application, numerous specific details are provided in the following detailed embodiments. Those skilled in the art should understand that this application can be implemented without certain specific details. In some instances, methods, means, components, and circuits well-known to those skilled in the art have not been described in detail in order to highlight the main points of this application.

[0039] Figure 1 This application shows a front view of a vertical electrical and communication shaft structure for a high-rise building according to an embodiment of the present application; as shown... Figure 1As shown, a vertical electrical and weak current shaft structure for a high-rise building includes: an electrical shaft 100 and two or more partition plates 200; the two or more partition plates 200 are horizontally placed inside the electrical shaft 100 and arranged sequentially along the length of the electrical shaft 100, which is suitable for dividing the cavity inside the electrical shaft 100 into multiple high-voltage chambers 110 suitable for placing high-voltage equipment 210 and multiple low-voltage chambers 120 suitable for placing low-voltage equipment 230, and the high-voltage chambers 110 and low-voltage chambers 120 are arranged alternately in sequence; each partition plate 200 is provided with a partition between its opposite side walls and the electrical shaft 100. A preset distance is used to form a cable tray installation area 220; each high-voltage chamber 110 is provided with a first fireproof partition 300, which is perpendicularly arranged and fixedly connected to the upper and lower partitions 200 of the high-voltage chamber 110; each low-voltage chamber 120 is provided with a second fireproof partition 400, which is perpendicularly arranged and fixedly connected to the upper and lower partitions 200 of the low-voltage chamber 120; the first fireproof partition 300 and the second fireproof partition 400 connected to each partition 200 are respectively located at both ends of the partition 200.

[0040] It should be noted that the electrical shaft 100 vertically penetrates the building, forming a cavity space inside the electrical shaft 100 that can accommodate high-voltage equipment 210, low-voltage equipment 230, and cable routing for each layer. Multiple partition plates 200 are placed horizontally within the cavity of the electrical shaft 100 and arranged sequentially along the length of the electrical shaft 100, thereby dividing the space inside the electrical shaft 100 into multiple high-voltage chambers 110 and multiple low-voltage chambers 120. The high-voltage chambers 110 and low-voltage chambers 120 are arranged alternately. That is, if one layer is designated as a high-voltage chamber 110, then the two layers above and below it are low-voltage chambers 120, and vice versa. The electric shaft 100 of this application adopts a series of alternating high-voltage and low-voltage chambers 110, 120, 110, 120, and so on, arranged from top to bottom or bottom to top. The partition plate 200 between the high-voltage and low-voltage chambers 110 and 120 serves to support the equipment while separating the adjacent high-voltage and low-voltage chambers 110 and 120, effectively isolating the high-voltage equipment 210 and the low-voltage equipment 230, avoiding electrical signal interference between them, and improving the uniformity of the arrangement of the high-voltage and low-voltage chambers 110 and 120 within the shaft, facilitating power supply to each floor of the building. The vertical layout of the high-voltage and low-voltage chambers 110 and 120 in this application can meet the functional requirements of conventional electric shafts. The first fireproof partition 300 and the second fireproof partition 400 are used to further seal the high-voltage chamber 110 and the low-voltage chamber 120, ensuring complete isolation between the adjacent high-voltage chamber 110 and the low-voltage chamber 120. Since each partition 200 and the opposite side walls of the electrical shaft 100 are provided with a cable tray installation area 220 formed by a preset distance, the high-voltage equipment 210 in each high-voltage chamber 110 can be connected by cable routing through the cable tray installation area 220 on one side; the low-voltage equipment 230 in each low-voltage chamber 120 can be connected by cable routing through the cable tray installation area 220 on the other side. The high-voltage cables and low-voltage cables are completely separated in the electrical shaft 100, further improving the overall anti-interference performance.

[0041] like Figure 14The diagram shows an existing electrical shaft structure design where high-voltage and low-voltage electrical shafts are located adjacent to each other on the same floor, separated by a mezzanine. This horizontal layout of the high-voltage and low-voltage shafts increases their footprint on each floor. This application provides a new structure for high-rise building layout design, effectively reducing the footprint of electrical shafts by up to 25% compared to a horizontal layout. This frees up more building space, enhances comfort, improves building quality, creates greater economic benefits for businesses, and increases their competitiveness.

[0042] In one possible implementation, the distance between each partition plate 200 is the same. It should be noted that the uniform spacing of the multiple partition plates 200 within the electrical shaft 100 ensures that each high-voltage electrical chamber 110 and each low-voltage electrical chamber 120 have the same height. Preferably, the distance between each partition plate 200 is the same as the floor height of a high-rise building. The partition plate 200 is a concrete floor slab.

[0043] In one possible implementation, each partition plate 200 is fixed to the opposite sidewall of the electric well shaft 100 on the side with the opening. For example... Figure 5 and Figure 6 As shown, the main body of the partition plate 200 is a rectangular plate structure. One side of the partition plate 200 is fixedly connected to the inner wall of the electric well shaft 100, and the inner wall of the electric well shaft 100 connected to the partition plate 200 is opposite to the opening side of the electric well shaft 100. Since the opening of the electric well shaft 100 is suitable for installing a door panel, when the staff opens the door panel, they can directly see the electrical equipment in the strong current chamber 110 and the weak current chamber 120, which facilitates the staff to inspect and maintain the electrical equipment.

[0044] like Figure 4 As shown, each partition plate 200 and the two opposing inner walls of the electrical shaft 100 are provided with the same preset distance to form through holes of the same size. These through holes serve as cable tray installation areas 220, suitable for installing cable trays. The cable trays can support the cables, facilitating their routing within the shaft and providing protection, thus improving the stability of the cable connections. Furthermore, the two cable tray installation areas 220 are located on adjacent sides of the side where the partition plate 200 is fixedly connected to the inner wall of the shaft 100.

[0045] Furthermore, the cable trays use enclosed metal troughs.

[0046] In one possible implementation, the preset distance between each partition plate 200 and the two opposing inner walls of the well casing 100 is 1 / 10 of the internal width of the electric well casing 100.

[0047] It should be noted that each high-voltage electrical chamber 110 is equipped with a first fireproof partition 300. The first fireproof partition 300 is fixedly connected to the upper and lower partition plates 200 of the high-voltage electrical chamber 110, and the first fireproof partition 300 is located on one side of one of the cable tray installation areas 220, thus shielding that cable tray installation area 220. Figure 1 As shown, the plane of the first fireproof partition 300 is perpendicular to the plane of the side of the partition plate 200 connecting the electric shaft 100. The plane of the first fireproof partition 300 is perpendicular to the planes of the upper and lower partition plates 200. The plane of the first fireproof partition 300 is parallel to the two side walls of the electric shaft 100. Under the combined action of the two partition plates 200 and the middle first fireproof partition 300, a "C"-shaped high-voltage electrical chamber 110 is formed. Only one side of the high-voltage electrical chamber 110 has a cable tray installation area 220 that is directly conductive. The other side of the cable tray installation area 220 is blocked by the first fireproof partition 300. Therefore, the cables in the high-voltage electrical chamber 110 can only be routed through one side of the cable tray installation area 220.

[0048] It should be noted that each low-voltage electrical chamber 120 is equipped with a second fireproof partition 400. The second fireproof partition 400 is fixedly connected to the upper and lower partition plates 200 of the low-voltage electrical chamber 120, and the second fireproof partition 400 is located on one side of one of the cable tray installation areas 220, thus shielding that cable tray installation area 220. Figure 1 As shown, the plane of the second fireproof partition 400 is perpendicular to the plane of the side of the partition plate 200 connecting the electric shaft 100, the plane of the second fireproof partition 400 is perpendicular to the planes of the upper and lower partition plates 200, and the plane of the second fireproof partition 400 is parallel to the two side walls of the electric shaft 100. Under the combined action of the two partition plates 200 and the middle second fireproof partition 400, a "C"-shaped weak current chamber 120 is formed. Only one side of the weak current chamber 120 has a cable tray installation area 220 that is directly conductive, while the other side of the cable tray installation area 220 is blocked by the second fireproof partition. Therefore, the cables of the strong current chamber 110 can only be routed through one side of the cable tray installation area 220.

[0049] The first fireproof partition 300 and the second fireproof partition 400 connected to each partition 200 are located at opposite ends of the partition 200. To further explain: since the high-voltage chamber 110 and the low-voltage chamber 120 are arranged alternately, the upper and lower sides of each partition 200 are different chambers (high-voltage chamber 110 or low-voltage chamber 120). Therefore, if the upper side of a partition 200 is connected to the first fireproof partition 300, its lower side is connected to the second fireproof partition 400; conversely, if the upper side of a partition 200 is connected to the second fireproof partition 400, its lower side is connected to the first fireproof partition 300. Regardless of the arrangement, the first fireproof partition 300 and the second fireproof partition 400 on the upper and lower sides of the partition 200 are located at opposite ends of the partition 200, thus respectively shielding the cable tray installation areas 220 on both sides of the partition 200. In summary, the opening sides of the "C"-shaped structures in all high-voltage chambers 110 and all low-voltage chambers 120 are oriented in the same direction. However, the opening sides of the "C"-shaped structures in the high-voltage chambers 110 and 120 are oriented oppositely. This ensures that the high-voltage equipment 210 in all high-voltage chambers 110 can only be routed through the cable tray mounting area 220 on the same side of all partitions 200, and the low-voltage equipment 230 in all low-voltage chambers 120 can only be routed through the cable tray mounting area 220 on the other side of all partitions 200. This completely isolates all high-voltage chambers 110 from all low-voltage chambers 120, and isolates the cables of the high-voltage equipment 210 from those of the low-voltage equipment 230. The overall structure is reasonable and highly reliable. (The above content can also be described as follows: all partition boards 200, all first fireproof partition boards 300 and all second fireproof partition boards 400 together form an "S"-shaped connection structure, with cables of high-voltage equipment 210 or low-voltage equipment 230 passing through both sides of the "S"-shaped structure.)

[0050] In one possible implementation, such as Figure 12 and Figure 13 As shown, both the first fireproof partition 300 and the second fireproof partition 400 are composed of two or more ALC wall panels 410, which are arranged sequentially and fixedly connected. Figure 7 As shown, each ALC wall panel 410 has the same structure, with a protrusion 411 on one side and a groove 412 on the other side. The protrusion 411 of one ALC wall panel 410 is embedded in the groove 412 of the adjacent ALC wall panel 410, thereby realizing the splicing of two or more ALC wall panels 410.

[0051] Furthermore, both the first fireproof partition 300 and the second fireproof partition 400 are composed of three ALC wall panels 410.

[0052] In one possible implementation, such as Figure 11 and Figure 12 As shown, a first fixing clamp 430 is provided between any two adjacent ALC wall panels 410. The main body of the first fixing clamp 430 is T-shaped. One end of the first fixing clamp 430 is embedded between the two adjacent ALC wall panels 410, and one side of the first fixing clamp 430 is attached to the partition plate 200. The nail 431 is inserted into the first fixing clamp 430 and the partition plate 200 in sequence, thereby fixing the first fixing clamp 430 and the partition plate 200.

[0053] In one possible implementation, a mortar layer 440 is provided between any two adjacent ALC wall panels 410 to seal the gap between the two adjacent ALC wall panels 410. The mortar layer 440 is made of ALC-specific mortar.

[0054] In one possible implementation, the four corners of the first fireproof partition 300 and the four corners of the second fireproof partition 400 are all fixedly connected to the partition plate 200 by second fixing pipe clamps 450. For example... Figure 8 and Figure 9 As shown, the main body of the second fixing clamp 450 has an "L"-shaped structure. One side of the second fixing clamp 450 is embedded in the first fireproof partition 300 or the second fireproof partition 400, and the other side of the second fixing clamp 450 contacts the partition plate 200. The second fixing clamp 450 and the partition plate 200 are fixedly connected by a nail 460. With the action of the four second fixing clamps 450, a stable connection can be achieved between the first fireproof partition 300 and the partition plate 200, and between the second fireproof partition 400 and the partition plate 200, preventing the first fireproof partition 300 and the second fireproof partition 400 from tilting or falling over. The second fixing clamp 450 uses an L-shaped ALC-specific fixing clamp.

[0055] In one possible implementation, adhesive layers 420 are filled between the upper and lower sides of the first fireproof partition 300 and the partition plate 200; adhesive layers 420 are also filled between the upper and lower sides of the second fireproof partition 400 and the partition plate 200. It should be noted that the adhesive layers 420 are used to improve the connection strength between the first fireproof partition 300 and the partition plate 200, and between the second fireproof partition 400 and the partition plate 200, ensuring the stable installation of the first fireproof partition 300 and the second fireproof partition 400, and also improving the sealing performance between the first fireproof partition 300 and the partition plate 200, and between the second fireproof partition 400 and the partition plate 200.

[0056] Furthermore, the adhesive layer 420 is made of ALC-specific mortar.

[0057] In one possible implementation, each first fireproof partition 300 has a cable tray on the side facing the high-voltage equipment 210 and each second fireproof partition 400 has a cable tray on the side facing the low-voltage equipment 230. The cable tray runs through the upper and lower sides of the first fireproof partition 300 or the second fireproof partition 400, and is suitable for concealed installation of pipelines.

[0058] Example 1: As Figure 12 As shown, the cable tray has two or more adjacent circular tubes 500 arranged inside, the cable passes through the circular tubes 500, and the cable tray is filled with a sealing layer 510. A protective cloth 520 is attached to one side of the opening of the cable tray.

[0059] Furthermore, the sealing layer 510 is made of ALC-specific mortar, and the protective cloth 520 is made of alkali-resistant fiberglass mesh.

[0060] Example 2: As Figure 13 As shown, there are two or more square tubes 600 inside the cable tray, and the cable passes through the square tubes 600.

[0061] From a resource utilization perspective, the vertical arrangement of the high-voltage electrical chamber 110 and the low-voltage electrical chamber 120 in this application effectively reduces the occupation of building space, making the internal space planning of the building more rational and efficient. In densely populated urban areas, this can indirectly increase other functional spaces, such as office / commercial spaces or residential spaces, thereby improving the utilization rate of the building's internal space. Secondly, during construction, the centralized mezzanine arrangement facilitates unified construction and management by the construction unit, reducing construction time and costs. It can more quickly meet the needs of society for residential, commercial, and office use. From a long-term perspective, it facilitates later maintenance and management. This arrangement helps to better integrate the power and low-voltage electrical systems, facilitates the monitoring and management of energy use, promotes the implementation of energy-saving measures, and has a positive significance for the sustainable development of society.

[0062] At the same time, this application makes reasonable use of the building's interior space and avoids Figure 14 The horizontal layout of the high-voltage electrical chamber 110 and low-voltage electrical chamber 120 avoids the waste of building space, allowing more space in the building to be used for other functions, improving the overall practicality of the building, and thus generating benefits for the enterprise. Secondly, it makes planning and construction more convenient, allowing the construction and installation team to install and debug electrical equipment more efficiently, while facilitating centralized maintenance and management, thereby reducing construction and operation and maintenance costs.

[0063] The various embodiments of this application have been described above. These descriptions are exemplary and not exhaustive, nor are they limited to the disclosed embodiments. Many modifications and variations will be apparent to those skilled in the art without departing from the scope and spirit of the described embodiments. The terminology used herein is chosen to best explain the principles, practical application, or improvement of the technology in the market, or to enable others skilled in the art to understand the embodiments disclosed herein.

Claims

1. A vertical electrical and communication shaft structure for a high-rise building, characterized in that, include: Electric well shaft, two or more partition plates; Two or more of the partition plates are placed horizontally inside the electric well shaft and arranged sequentially along the length of the electric well shaft. This is suitable for dividing the cavity inside the electric well shaft into multiple high-voltage chambers suitable for placing high-voltage equipment and multiple low-voltage chambers suitable for placing low-voltage equipment. The high-voltage chambers and the low-voltage chambers are arranged alternately in sequence. Each of the partition plates is provided with a preset distance between its opposite side walls and the electric well shaft to form a cable tray installation area; Each of the high-voltage chambers is provided with a first fireproof partition, which is perpendicularly arranged and fixedly connected to the upper and lower partitions of the high-voltage chamber. Each of the aforementioned weak current chambers is provided with a second fireproof partition, which is perpendicularly arranged and fixedly connected to the upper and lower partitions of the weak current chamber. The first fireproof partition and the second fireproof partition connected to each of the partition panels are located at opposite ends of the partition panel.

2. The vertical electrical and communication shaft structure for high-rise buildings according to claim 1, characterized in that, The distance between each of the partition plates is the same.

3. The vertical electrical and communication shaft structure for high-rise buildings according to claim 1, characterized in that, Each of the aforementioned partition plates is fixed to the opposite sidewall of the electric well shaft on the side with the opening.

4. The vertical electrical and communication shaft structure for high-rise buildings according to claim 1, characterized in that, The preset distance is 1 / 10 of the internal width of the electric well shaft.

5. The vertical electrical and communication shaft structure for high-rise buildings according to claim 1, characterized in that, The upper and lower sides of each of the first fireproof partitions and the upper and lower sides of each of the second fireproof partitions are fixedly connected to the partition plate by fixing pipe clamps.

6. The vertical electrical and communication shaft structure for high-rise buildings according to claim 5, characterized in that, An adhesive layer is provided between the upper and lower sides of each of the first fireproof partitions and the partition plate; an adhesive layer is provided between the upper and lower sides of each of the second fireproof partitions and the partition plate.

7. The vertical electrical and communication shaft structure for high-rise buildings according to claim 6, characterized in that, Each of the first fireproof partitions and each of the second fireproof partitions consists of two or more ALC wall panels.

8. The vertical electrical and communication shaft structure for high-rise buildings according to claim 6, characterized in that, Each of the first fireproof partitions and each of the second fireproof partitions is provided with a cable channel.