CN210067006U - Assembled wall component with built-in electric pipeline and assembled wallboard installation system - Google Patents

Abstract

The utility model discloses a prefabricated wall member with built-in electrical pipelines and a prefabricated wall panel installation system. The prefabricated wall member is internally provided with a reserved channel through which a power supply pipeline passes, and the upper and lower ends of the reserved channel are respectively It extends to the roof and ground of the house, and is respectively connected with the upper pipeline channel on the roof and the lower pipeline channel on the ground, and the reserved channel is provided with a power point interface. When the prefabricated wall member is manufactured, a reserved channel for the power supply pipeline to pass through is reserved in its interior, and the upper pipeline channel and the lower pipeline channel are connected through the reserved channel, so as to optimize the spatial arrangement of the power supply pipeline and save space. It enables the staff to easily and conveniently perform the wiring work when assembling the prefabricated wall panels or when the house is rebuilt in the later stage, and solves the problem that the prefabricated wall panels in the prior art need to be laid out by pipelines, which leads to the high construction cost of the power pipelines. And it cannot be retrofitted later, and the use flexibility is poor.

Description

Prefabricated wall components with built-in electrical conduits and prefabricated wall panel installation systems

technical field

The utility model relates to the technical field of prefabricated buildings, in particular to a prefabricated wall member with built-in electrical pipelines and a prefabricated wall panel installation system.

Background technique

A prefabricated building refers to a building assembled from prefabricated components on site. A large number of building parts of prefabricated buildings are produced and processed in the workshop, and the assembly operation is carried out on the construction site, which greatly improves the production efficiency and reduces the corresponding component cost compared with the original cast-in-place operation. Prefabricated buildings not only meet the requirements of green buildings, but also effectively reduce the construction cost of the entire building.

However, in the process of arranging the power pipelines of the existing prefabricated buildings, the wall needs to be slotted, and the power pipelines are arranged on the surface of the wall by means of external application of the pipelines, and the power pipelines are fixed at points to avoid the position movement of the power pipelines. . After the above work is completed, it is necessary to sacrifice the clearance height and carry out the work of laying the ground pipeline before the power pipeline layout can be completed. The above-mentioned pipeline layout method of external pipeline needs to destroy the original wall, which not only increases the construction difficulty and construction cost, but also generates construction waste, which increases the construction cost of the prefabricated building. Moreover, for the power pipelines arranged by the external application of the pipelines, the position of the power pipelines is fixed, cannot be expanded or moved, and there is no possibility of post-transformation during the use process, resulting in the problem of poor flexibility in the layout of the power pipelines.

Utility model content

Therefore, the present invention aims to provide a prefabricated wall member with built-in electrical pipelines and a prefabricated wall panel installation system, so as to solve the problem that the prefabricated wall panels in the prior art need to be laid out by means of pipeline external application, resulting in electrical The pipeline construction cost is high, it cannot be retrofitted later, and the use flexibility is poor. To this end, the utility model provides an assembled wall member with a built-in electrical pipeline,

The prefabricated wall member is provided with at least one reserved channel through which the power supply pipeline passes. The upper and lower ends of the reserved channel extend to the roof and the ground of the house respectively, and are respectively connected with the upper pipeline channel located on the roof and the upper pipeline channel located on the roof. The lower pipeline passages on the ground are connected, and at least one power consumption point interface extending to the outside of the prefabricated wall member is arranged in the length direction of the reserved passage.

The prefabricated wall components are cast and formed.

There are a plurality of reserved channels, and the plurality of reserved channels are arranged in a horizontal direction inside the prefabricated wall member.

A plurality of the reserved passages are evenly arranged in the horizontal direction inside the prefabricated wall member.

The reserved passage is arranged perpendicular to the roof and/or the ground in a vertical direction.

A plurality of the electrical point interfaces are arranged in the length direction of the reserved channel.

The upper pipeline channel includes the inner accommodating space of the suspended ceiling located on the roof, and/or the sky keel located on the roof for supporting the prefabricated wall member and/or supporting the suspended ceiling.

The lower pipeline channel includes a ground joist on the roof for supporting the fabricated wall member.

The prefabricated wall member is provided with a power rail that communicates with the power point interface and is used for installing a socket to change the position of power supply.

The power rail is arranged along the horizontal direction of the fabricated wall member.

The outer contour of the prefabricated wall member is wrapped with a frame for increasing the strength of the prefabricated wall member, and the width of the frame is smaller than the thickness of the outer contour of the prefabricated wall member.

The frame is made of metal.

The frame forms a closed annular structure along the outer contour of the prefabricated wall member.

The frame is arranged at the central position in the thickness direction of the prefabricated wall member.

The outer contour of the prefabricated wall member is provided with a strip groove for accommodating the frame, the frame is embedded in the strip groove, and the prefabricated wall member is used for increasing the Its strength is connected to the steel cage.

A prefabricated wall panel mounting system includes

In the above-mentioned prefabricated wall components, a plurality of the prefabricated wall components are spliced to form prefabricated wall panels;

The upper pipeline channel is arranged on the roof of the house and communicates with the reserved channel in the prefabricated wall member;

The lower pipeline channel is arranged on the ground of the house and communicates with the reserved channel in the prefabricated wall member.

The technical scheme of the present utility model has the following advantages:

1. The prefabricated wall member with built-in electrical pipeline provided by the present utility model, the prefabricated wall member is internally provided with at least one reserved channel through which the power supply pipeline passes, and the upper and lower ends of the reserved channel are respectively extended to The roof and the ground of the house are respectively communicated with the upper pipeline channel located on the roof and the lower pipeline channel located on the ground, and the reserved channel is arranged with at least a A power point interface. When manufacturing the prefabricated wall member, a reserved channel for the power supply pipeline to pass through is reserved inside the prefabricated wall member, and a power point interface is reserved on the prefabricated wall member, and the above-mentioned reserved channel is connected to the upper pipeline channel and the The lower pipeline channel can effectively optimize the spatial arrangement of the power supply pipeline and save space. To avoid the problem in the prior art that after the completion of the wall construction, it is necessary to sacrifice the clearance height and carry out the work of laying the ground pipelines in order to complete the layout of the power pipelines. In addition, by pre-producing and processing reserved channels and power point interfaces in the production of prefabricated wall components, the staff can easily and conveniently carry out splicing of prefabricated wall panels or later house reconstruction. The wiring work solves the problem that the prefabricated wall panels in the prior art need to be laid out by means of pipeline external application, which leads to the need to destroy the original wall in the existing construction method, which not only increases the construction difficulty and construction cost, but also generates construction waste. , which increases the construction cost of prefabricated buildings. Moreover, by pre-manufacturing and processing the reserved channel and the power point interface in the production of the prefabricated wall components, so that in the later transformation process, another reserved channel and the power point interface can be used. The wiring can effectively solve the problem of poor flexibility in the layout of power pipelines due to the existing power pipelines laid out by external pipelines, the position of the power pipelines is fixed, cannot be expanded or moved, and there is no possibility of later transformation during use.

2. The prefabricated wall member with built-in electrical pipeline provided by the present invention is provided with a plurality of reserved passages, and the plurality of reserved passages are arranged in the horizontal direction inside the prefabricated wall member. The prefabricated wall component has multiple reserved channels in the horizontal direction and the power point interface on the reserved channel, so that when assembling the prefabricated wall panel, the staff can choose to pass different prefabs according to actual needs. Leave the channel and the power point interface to arrange the power supply pipeline to increase the adaptability of the prefabricated wall panel.

3. The prefabricated wall member with built-in electrical pipelines provided by the present utility model, by arranging a plurality of reserved channels evenly in the horizontal direction inside the prefabricated wall member. Thereby, the adaptability of the prefabricated wall components is further improved.

4. The prefabricated wall components with built-in electrical pipelines provided by the present utility model, the reserved passages are arranged to be perpendicular to the roof and/or the ground along the vertical direction, so as to ensure that the prefabricated wall components are suitable for At the same time, it is convenient for manufacturers to manufacture prefabricated wall components with reserved channels.

5. In the prefabricated wall member with built-in electrical pipelines provided by the present invention, a plurality of electrical point interfaces are arranged along the length direction of the reserved passage. Multiple power point interfaces are arranged along the length of the reserved channel, so that users can choose power point interfaces at different heights or different positions according to their actual needs, further improving the adaptability of prefabricated wall components.

6. The prefabricated wall member with built-in electrical pipelines provided by the present utility model, the upper pipeline channel comprises a suspended ceiling located on the roof and its inner accommodation space, and/or is located on the roof for supporting the prefabricated A wall member and/or a keel supporting the suspended ceiling. By setting the upper end of the reserved channel to be directly connected with the inner accommodating space of the suspended ceiling and/or the inner cavity of the keel, it is thus avoided in the prior art that it is necessary to sacrifice the headroom after the completion of the wall construction to carry out the laying of the roof pipeline. The work to be able to complete the problem of power pipeline layout. The power lines can be directly accommodated in the existing ceiling and/or the keel, so as to make full use of the existing space, increase the headroom, and improve the user experience.

7. The prefabricated wall member with built-in electrical pipeline provided by the present invention, the lower pipeline channel comprises a ground keel located on the roof for supporting the prefabricated wall member. This avoids the problem in the prior art that after the completion of the wall construction, it is necessary to sacrifice the clearance height and carry out the work of laying the ground pipelines in order to complete the layout of the power pipelines. The power pipeline can be directly accommodated in the existing ground keel, so as to make full use of the existing space, increase the headroom, and improve the user experience.

8. The prefabricated wall member with built-in electrical pipeline provided by the present utility model, the prefabricated wall member is provided with the electric power which is connected with the power point interface and is used for installing the socket to change the position of the power supply guide. The socket is slidably installed on the above-mentioned power rail, so that the position of the socket on the power rail can be adjusted according to actual needs, and the position of the socket can be adjusted within a small range, thereby further improving the adaptability of the prefabricated wall components.

9. The prefabricated wall member with built-in electrical pipeline provided by the present invention, the electric guide rail is arranged along the horizontal direction of the prefabricated wall member. Because the reserved channels are arranged in the horizontal direction of the prefabricated wall components, if a large number of reserved channels are set up, it will inevitably affect the strength of the prefabricated wall panels and affect the safety performance. Setting the power guide rail in the horizontal direction can effectively reduce the number of reserved channels on the premise of ensuring the adaptability of the prefabricated wallboard, thereby ensuring the strength of the prefabricated wallboard and reducing the manufacturing cost of the prefabricated wallboard.

10. The prefabricated wall member with built-in electrical pipeline provided by the present utility model, the outer contour of the prefabricated wall member is wrapped with a frame for increasing the strength of the prefabricated wall member, and the frame can be used to increase the strength of the prefabricated wall member. The wall components and the wall panels they consist of have an overall reinforcement effect, which can effectively reduce the thickness of the wall under the condition of achieving the same wall performance, so as to achieve the purpose of increasing the area of the house; at the same time, the frame can also effectively protect the prefabricated type. The corners and tongues of the wall components should be used to avoid bumping of the corners and tongues during handling and installation, so as not to affect the installation and connection of the wall, the construction of pipelines and decorative surfaces due to the collision of the prefabricated wall components. and the performance of the entire wall. While improving the strength of the prefabricated wall member, since the width of the frame is smaller than the thickness of the outer contour of the prefabricated wall member, the frame forms a concave-convex structure on the upper edge of the outer contour of the prefabricated wall member. The structure can effectively make the gap between adjacent prefabricated wall components more compact after the process of caulking and other processes, thereby improving the sound insulation and fire resistance of the entire wall.

11. The prefabricated wall components with built-in electrical pipelines provided by the present utility model, the frame is made of metal material, the frame of the metal material is more straight, compared with the prefabricated wall components made of concrete material, it is less likely to have gaps, so that the The connected frames are connected more closely, thereby avoiding the gap between adjacent prefabricated wall components, and further improving the sound insulation and fire resistance of the entire wall.

12. In the prefabricated wall member with built-in electrical pipeline provided by the present invention, the frame forms a closed annular structure along the outer contour of the prefabricated wall member. The frame of the above-mentioned closed annular structure is more convenient for the production and processing of the staff, and the surrounding of the outer contour edge of the entire prefabricated wall member by the frame can further enhance the overall reinforcement effect on the prefabricated wall member and the wall panels it consists of.

13. The prefabricated wall member with built-in electrical pipelines provided by the present utility model, by setting the frame at the central position in the thickness direction of the prefabricated wall member. Therefore, the prefabricated wall components are uniformly stressed, and the strength of the prefabricated wall components is further improved. Moreover, by arranging the frame at the central position in the thickness direction of the prefabricated wall member, the fillers on both sides of the frame of the prefabricated wall member can be the same, so as to ensure the connection strength between the prefabricated wall members.

Description of drawings

In order to more clearly illustrate the specific embodiments of the present invention or the technical solutions in the prior art, the following will briefly introduce the accompanying drawings that need to be used in the description of the specific embodiments or the prior art. Obviously, the following descriptions The accompanying drawings are some embodiments of the present invention. For those of ordinary skill in the art, other drawings can also be obtained based on these drawings without creative efforts.

Fig. 1 is the structural representation of the prefabricated wall panel installation system provided by the utility model;

Fig. 2 is the connection schematic diagram of the prefabricated wall member provided by the utility model and the upper pipeline channel and the lower pipeline channel respectively;

FIG. 3 is a schematic structural diagram of a prefabricated wall member provided by the present invention.

Description of reference numbers:

1-fabricated wall components; 2-reserved channel; 3-upper pipeline channel; 4-lower pipeline channel; 5-power point interface; 6-day keel; 7-ground keel; 8-power rail; -Prefabricated wall panel; 10-socket; 11-frame.

Detailed ways

The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are a part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative work fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner" and "outer" The orientation or positional relationship indicated by etc. is based on the orientation or positional relationship shown in the accompanying drawings, which is only for the convenience of describing the present invention and simplifying the description, rather than indicating or implying that the referred device or element must have a specific orientation, with a specific orientation. Therefore, it should not be construed as a limitation on the present invention. Furthermore, the terms "first", "second", and "third" are used for descriptive purposes only and should not be construed to indicate or imply relative importance.

In the description of the present invention, it should be noted that, unless otherwise expressly specified and limited, the terms "installed", "connected" and "connected" should be understood in a broad sense, for example, it may be a fixed connection or a connectable connection. Detachable connection, or integral connection; may be mechanical connection or electrical connection; may be direct connection, or indirect connection through an intermediate medium, or internal communication between two components. For those of ordinary skill in the art, the specific meanings of the above terms in the present invention can be understood in specific situations.

In addition, the technical features involved in the different embodiments of the present invention described below can be combined with each other as long as there is no conflict with each other.

Example 1

This embodiment provides a prefabricated wall panel installation system, as shown in FIG. 1 , comprising:

As shown in FIG. 1 to FIG. 3 , a prefabricated wall member 1 , a plurality of the prefabricated wall members 1 are assembled to form a prefabricated wall panel 9 . The prefabricated wall member 1 is formed by pouring, and is provided with a plurality of reserved channels 2 through which the power supply pipelines pass. The upper pipeline channel 3 of the roof and the lower pipeline channel 4 located on the ground are connected, and the reserved channel 2 is arranged with a plurality of power point interfaces extending to the outside of the prefabricated wall member 1 in the length direction. 5. The number of power point interfaces 5 on each reserved channel 2 is 4. When the prefabricated wall member 1 is produced, a reserved channel 2 for the power supply pipeline to pass through is reserved in the interior of the prefabricated wall member 1 and a power point interface 5 is reserved on the prefabricated wall member 1, and the above-mentioned reserved channel is connected. The upper pipeline channel 3 and the lower pipeline channel 4 can effectively optimize the spatial arrangement of the power supply pipeline and save space. To avoid the problem in the prior art that after the completion of the wall construction, it is necessary to sacrifice the clearance height and carry out the work of laying the ground pipelines in order to complete the layout of the power pipelines. Moreover, by pre-producing and processing the reserved channel 2 and the power point interface 5 in the interior of the prefabricated wall member 1, it is easy for the staff to splicing the prefabricated wall panel or remodeling the house later. It is convenient to carry out the wiring work, and solve the problem that the prefabricated wall panels in the prior art need to be laid out by means of external application of pipelines, which leads to the need to destroy the original wall in the existing construction method, which not only increases the construction difficulty and construction cost, but also generates It eliminates construction waste and increases the construction cost of prefabricated buildings. Moreover, when the prefabricated wall member 1 is produced, the reserved channel 2 and the power point interface 5 are pre-produced and processed in the interior thereof, so that another reserved channel 2 and the power consumption can be passed through in the later transformation process. The point interface 5 is used for wiring, which can effectively solve the problem that the position of the power pipeline is fixed, non-expandable, non-movable, and there is no possibility of post-transformation during use, resulting in the layout of the power pipeline. The problem of poor flexibility;

The upper pipeline channel 3 is arranged on the roof of the house and communicates with the reserved channel 2 in the prefabricated wall member 1. The upper pipeline channel 3 includes the inner accommodating space of the suspended ceiling located on the roof, and is located in the ceiling. The roof is used to support the sky keel 6 of the prefabricated wall member 1, so as to avoid the need to sacrifice the headroom after the completion of the wall construction in the prior art, and carry out the work of laying the roof pipeline to complete the power pipeline layout. The problem. The power pipeline can be directly accommodated in the existing ceiling and/or the keel 6, so as to make full use of the existing space, increase the headroom, and improve the user experience;

The lower pipeline channel 4 is arranged on the ground of the house and communicates with the reserved channel 2 in the prefabricated wall member 1. The lower pipeline channel 4 includes a structure located on the roof for supporting the prefabricated wall member. 1 of the ground keel 7, so as to avoid the problem in the prior art that after the completion of the wall construction, it is necessary to sacrifice the clearance height and carry out the work of laying the ground pipelines to complete the power pipeline layout. The power pipeline can be directly accommodated in the existing ground keel 7, so as to make full use of the existing space, increase the headroom, and improve the user experience.

In this embodiment, as shown in FIG. 1 , there are a plurality of the reserved channels 2 , and the plurality of reserved channels 2 are arranged in the horizontal direction inside the prefabricated wall member 1 and in the vertical direction Set perpendicular to the roof or the ground. Therefore, when assembling the prefabricated wall panels, the staff can selectively arrange power supply pipelines through different reserved channels 2 and power point interfaces 5 according to actual needs, thereby increasing the adaptability of the prefabricated wall panels. Moreover, the above-mentioned plurality of reserved channels 2 are evenly arranged in the horizontal direction inside the prefabricated wall member 1 , thereby further improving the adaptability of the prefabricated wall member 1 . Moreover, a plurality of the power consumption point interfaces 5 are arranged in the length direction of the reserved channel 2, so that the user can select the power consumption point interfaces 5 at different heights or different positions according to their actual needs, further improving the Adaptability of prefabricated wall elements 1.

In this embodiment, as shown in FIG. 2 , the prefabricated wall member 1 is provided with a power rail 8 that communicates with the power point interface 5 and is used for installing the socket 10 to change the position of power supply. The socket 10 is slidably installed on the above-mentioned power rail 8, so that the position of the socket 10 on the power rail 8 can be adjusted according to actual needs, and then the position of the socket 10 can be adjusted within a small range to further improve the prefabricated wall. Component 1's adaptability. Furthermore, the above-mentioned power guide rails 8 are arranged along the horizontal direction of the prefabricated wall member 1 . Because the reserved passages 2 are arranged in the horizontal direction of the prefabricated wall member 1, if a large number of reserved passages 2 are provided, the strength of the prefabricated wall panel will inevitably be affected, and the safety performance will be affected. Setting the power guide rail 8 in the horizontal direction can effectively reduce the number of reserved channels 2 on the premise of ensuring the adaptability of the prefabricated wallboard, thereby ensuring the strength of the prefabricated wallboard and reducing the production of the prefabricated wallboard. cost.

In this embodiment, as shown in FIG. 3 , the outer contour of the prefabricated wall member 1 is wrapped with a frame 11 for increasing the strength of the prefabricated wall member 1 , and the frame 11 is made of metal. The width is smaller than the thickness of the outer contour of the prefabricated wall member 1 . Through the frame 11, the prefabricated wall member 1 and the wall panels formed by it can be reinforced as a whole, and the thickness of the wall can be effectively reduced under the condition of achieving the same wall performance, so as to achieve the purpose of increasing the area of the house; at the same time, The frame can also effectively protect the corners and grooves of the prefabricated wall member 1, and avoid the corners and grooves from bumping during the handling and installation process, so as not to affect the wall due to the collision of the prefabricated wall member 1. The installation and connection, the construction of pipeline and decorative surface and the performance of the whole wall. While improving the strength of the prefabricated wall member, since the width of the frame 11 is smaller than the thickness of the outer contour of the prefabricated wall member, the frame forms a concave-convex structure on the upper edge of the outer contour of the prefabricated wall member. The concave-convex structure can effectively make the gap between adjacent prefabricated wall components more compact after filling and other processes, thereby improving the sound insulation and fire resistance of the entire wall. The frame 11 forms a closed annular structure along the outer contour of the prefabricated wall member 1 . The outer contour of the prefabricated wall member 1 is provided with a strip-shaped groove for accommodating the frame 11 . Connected with steel cages inside to increase its strength. The frame of the above-mentioned closed annular structure is more convenient for the production and processing of the staff, and the outer contour edge of the entire prefabricated wall member 1 is surrounded by the frame 11, which can further enhance the overall production of the prefabricated wall member 1 and the wall panels it consists of. reinforcement. The frame 11 is arranged at the central position of the prefabricated wall member 1 in the thickness direction, so that the prefabricated wall member is uniformly stressed and further improves the strength of the prefabricated wall member. Moreover, by setting the frame 11 at the central position in the thickness direction of the prefabricated wall member, the fillers on both sides of the frame of the prefabricated wall member can be made the same, so as to ensure the connection strength between the prefabricated wall members. .

Of course, the application of the present utility model does not specifically limit the arrangement of the reserved channel 2. In other embodiments, the designer has pre-designed the arrangement position of the power pipeline, and the manufacturer can arrange the prefabricated wall member 1 according to the actual needs of the user. One or more reserved channels 2 are reserved.

Of course, the present application does not specifically limit whether the power guide rail 8 is provided. In other embodiments, the power guide rail 8 is not pre-installed on the prefabricated wall member 1 .

Of course, the utility model application does not make specific restrictions on whether to set the power guide rail 8. In other embodiments, of course, the utility model application does not specifically limit the number of power point interfaces 5. In other embodiments, in the One or more of the power point interface 5 is arranged in the length direction of the reserved channel 2

Of course, the present application does not specifically limit the material of the frame 11. In other embodiments, the frame 11 is made of high-strength plastic material.

Obviously, the above-mentioned embodiments are only examples for clear description, and are not intended to limit the implementation manner. For those of ordinary skill in the art, changes or modifications in other different forms can also be made on the basis of the above description. There is no need and cannot be exhaustive of all implementations here. And the obvious changes or changes derived from this are still within the protection scope of the present invention.

Claims (10)

1. An assembled wall component with built-in electric pipelines is characterized in that,

the assembled wall component is characterized in that at least one reserved channel (2) through which a power supply pipeline passes is arranged in the assembled wall component (1), the upper end and the lower end of the reserved channel (2) extend to the roof and the ground of a house respectively and are communicated with an upper pipeline channel (3) located on the roof and a lower pipeline channel (4) located on the ground respectively, and at least one electricity utilization point position interface (5) extending to the outside of the assembled wall component (1) is arranged in the length direction of the reserved channel (2).

2. The assembled wall member with built-in electric piping according to claim 1, wherein said pre-passage (2) is plural, and plural of said pre-passages (2) are arranged in a horizontal direction inside said assembled wall member (1).

3. The assembly wall member with built-in electric piping according to claim 2, wherein a plurality of said pre-passages (2) are uniformly arranged in a horizontal direction inside said assembly wall member (1).

4. Assembled wall element with built-in electrical conduits according to claim 2, characterized in that the pre-channel (2) is arranged vertically perpendicular to the roof and/or the ground.

5. The assembled wall member with built-in electric piping according to claim 4, wherein a plurality of said electric point using interfaces (5) are arranged in a length direction of said reserve passage (2).

6. Assembled wall element with built-in electrical conduits according to claim 1, characterized in that the upper conduit channel (3) comprises a ceiling internal housing space located at the roof and/or a ceiling keel (6) located at the roof for supporting the assembled wall element (1) and/or the ceiling.

7. Assembled wall element with built-in electrical conduits according to claim 1, characterized in that the lower pipeline channel (4) comprises a keel (7) at the roof for supporting the assembled wall element (1).

8. The assembly wall member with built-in electric pipeline according to any one of claims 1 to 7, characterized in that the assembly wall member (1) is provided with a power rail (8) communicating with the power point interface (5) for installing a socket (10) to change the position of power supply.

9. The assembly wall member with built-in electric piping according to claim 8, characterized in that said electric power rail (8) is disposed along the horizontal direction of said assembly wall member (1).

10. An assembly wallboard mounting system, comprising

A fabricated wall element (1) according to any one of claims 1-9, a plurality of said fabricated wall elements (1) being assembled to form a fabricated wall panel (9);

the upper pipeline channel (3) is arranged on the roof of the house and is communicated with the reserved channel (2) in the assembled wall body component (1);

and the lower pipeline channel (4) is arranged on the ground of the house and is communicated with the reserved channel (2) in the assembled wall body component (1).

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