CN118128217A - Green energy-saving assembled building wall member and use method thereof - Google Patents

Abstract

The green energy-saving assembled building wall component comprises a wall body, wherein the lower end of the wall body is provided with a containing cavity, a fixed keel is correspondingly inserted in the containing cavity, and the lower end of the fixed keel is fixed on a base; a position adjusting mechanism is arranged between the wall body and the base, the upper end of the position adjusting mechanism is connected with the lower surface of the wall body, the lower end of the position adjusting mechanism is fixedly connected with the base, and a fixed keel is arranged in the position adjusting mechanism in a penetrating manner and is inserted into a corresponding keel sleeve which is arranged in a containing cavity of the wall body; the position adjusting mechanism drives the wall body to adjust angles in the front-back direction and the left-right direction on the horizontal plane. The invention aims to provide a green energy-saving assembled building wall component, which can realize the rapid plug-in connection of a base and a wall under the condition that a fixed keel is deformed or out of tolerance, and can realize the adjustment of the position of the wall under the condition that the wall is fixed without an external tool, thereby effectively reducing the construction difficulty and improving the construction efficiency.

Description

Green energy-saving assembled building wall member and use method thereof

Technical Field

The invention relates to the technical field of building materials, in particular to a green energy-saving assembled building wall member and a use method thereof.

Background

The green energy-saving assembled building wall component is characterized in that wall boards and various wall decoration components are prefabricated in factories, the manufactured wall boards are transported to a construction site for assembly, and the installation is completed by a dry construction method, specifically, the wall boards are directly installed on the wall by fixing keels on the wall surfaces. The assembly type wallboard mounting process can be used for blank wall mounting, is convenient to mount and shortens the construction period.

At present, in the assembly process of the wall body, the assembly type building wall body is spliced and fixed through a containing cavity arranged at the bottom of the wall body and a fixed keel on a base, and the parallelism and the perpendicularity of the wall body are corrected through an external tool before the fixing process, but in the splicing and fixing process of the assembly type building wall body, the fixed keel is easy to deform in the conveying or splicing process, or the matched size of the fixed keel and the containing cavity is out of tolerance, so that the splicing is difficult or the wall body is inclined; in the wall correction process, the fixture is fixed on the outer surface of the wall body, so that the wall body is easily damaged, and meanwhile, the construction difficulty is increased, and the construction process is influenced.

The inventor knows a green energy-saving assembled building wall component (202310301880.5), including the building wall, the building wall comprises building wall main part and wall buttress, the both sides of building wall main part are respectively fixedly provided with a wall buttress, the inside of building wall main part is provided with building wall main part steel reinforcement cage, the inside of wall buttress is provided with wall buttress steel reinforcement cage, the lateral part of wall buttress steel reinforcement cage is in the outside of wall buttress, building wall main part steel reinforcement cage and wall buttress steel reinforcement cage weave into an organic whole, the top of wall buttress steel reinforcement cage is provided with the assembly steel reinforcement cage, the lower part of assembly steel reinforcement cage inserts in the wall buttress steel reinforcement cage, and the assembly steel reinforcement cage and wall buttress steel reinforcement cage weave into an organic whole, the lower part inside of wall buttress is provided with assembly steel reinforcement cage spread groove, and the inboard top of assembly steel reinforcement cage spread groove sets up into the top surface of slope, set up the pouring gate with the highest point position of assembly steel reinforcement cage spread groove on the wall buttress. However, in the process of implementing the technical solution in the embodiment of the present application, the present inventors have found that at least the following technical problems exist in the above technology:

the fixed keel is easy to deform in the process of transportation or splicing, or the splicing is difficult or the wall body is inclined due to the out-of-tolerance of the matched sizes of the fixed keel and the accommodating cavity; in the wall body position correction process, the tool is fixed on the outer surface of the wall body, so that the wall body is easily damaged, and the construction difficulty is increased, so that the construction process is influenced.

Disclosure of Invention

The invention aims to provide a green energy-saving assembled building wall component, which can realize the rapid plug-in connection of a base and a wall under the condition that a fixed keel is deformed or out of tolerance, and can realize the adjustment of the position of the wall under the condition that the wall is fixed without an external tool, thereby effectively reducing the construction difficulty and improving the construction efficiency.

The invention adopts the following technical scheme:

The green energy-saving assembled building wall component comprises a wall body, wherein the lower end of the wall body is provided with a containing cavity, a fixed keel is correspondingly inserted in the containing cavity, and the lower end of the fixed keel is fixed on a base; a position adjusting mechanism is arranged between the wall body and the base, the upper end of the position adjusting mechanism is connected with the lower surface of the wall body, the lower end of the position adjusting mechanism is fixedly connected with the base, and a fixed keel is arranged in the position adjusting mechanism in a penetrating manner and is inserted into a corresponding keel sleeve which is arranged in a containing cavity of the wall body; the position adjusting mechanism drives the wall body to adjust angles in the front-back direction and the left-right direction on the horizontal plane.

Further, the keel sleeve comprises a keel sleeve coaxially arranged in the accommodating cavity, and the keel sleeve is in sliding connection with the accommodating cavity along the radial direction of the accommodating cavity through outer supporting shafts arranged on two sides of the keel sleeve; a keel inner sleeve is coaxially inserted in the keel outer sleeve, and the keel inner sleeve is in sliding connection with the keel outer sleeve along the radial direction of the accommodating cavity through inner supporting shafts arranged on two sides of the keel inner sleeve; the movement direction of the keel outer sleeve and the movement direction of the keel inner sleeve in the same accommodating cavity are vertical.

Further, the axes formed by the outer supporting shafts of the keel jackets in the adjacent accommodating cavities form an included angle of 90 degrees.

Further, the position adjusting mechanism comprises a support frame, the upper surface of the support frame is contacted with the lower end face of the wall body, the left side of the lower end of the support frame is connected with a swinging structure in a sliding manner, and the swinging structure is fixedly connected to one side of the base; the swinging structure is used for adjusting the verticality between the front surface of the wall body and the upper surface of the base; the right side of the lower end of the support frame is connected with a moving structure in a sliding manner, the moving structure is fixedly connected to the other side of the base, and the moving structure is used for adjusting the levelness of the upper surface of the wall body and the upper surface of the base; the through hole has been seted up to support frame intermediate position, and fixed fossil fragments wear to locate the support frame through the through-hole.

Further, the swing structure comprises a stabilizer bar, one end of the stabilizer bar is connected with an arc-shaped sliding rail arranged on the base, and the sliding rail is in sliding connection with the support frame through an arc-shaped sliding rail groove arranged on the corresponding side of the support frame; the sliding rail is hinged with the base through a hinge seat, and a hinge shaft which is arranged horizontally and front and back is arranged in the hinge seat; the turbine is connected to the stabilizer bar other end, and with turbine complex drive worm connection support frame, and drive worm wears to locate the terminal surface and rotate with the support frame and be connected around the support frame.

Further, the moving structure comprises a driving screw, one end of the driving screw is connected with the moving block through threaded fit, the other end of the driving screw is rotationally connected with a screw supporting seat, the screw supporting seat is fixed on the base, the upper surface of the moving block is an arc-shaped surface matched with the sliding rail, the lower end of the moving block is in sliding connection with the supporting frame, and the left and right heights of the arc-shaped surface of the upper surface of the moving block are different.

Further, the upper surface of the moving block is an arc surface with high left and low right; the lower end surface of the supporting frame contacted with the moving block is provided with an arc-shaped groove matched with the upper surface of the moving block; and the arc-shaped groove is an arc-shaped groove with high left and low right.

Further, a dovetail arc-shaped limit strip is arranged on the upper surface of the sliding rail along the circumferential direction; the sliding rail groove is an arc dovetail groove matched with the arc limiting strip.

Further, the outer support shaft and the inner support shaft are circular shafts.

Further, the method sequentially comprises the following steps:

A: a position adjusting mechanism 5 is arranged above the base 2, so that a fixed keel 3 fixed above the base 2 is inserted into a corresponding through hole formed on the upper surface of the supporting frame 53;

B: moving the prefabricated wall body 1 to the position above the base 2 through hoisting equipment, and manually adjusting the angle of the wall body 1 to enable each fixed keel 3 to correspond to the position of the corresponding keel inner sleeve 42;

C: lowering the prefabricated wall body 1 through hoisting equipment, and adjusting the horizontal position and angle of the keel inner sleeves 42 in the accommodating cavity 11 in real time, so that each fixed keel 3 is inserted into the corresponding keel inner sleeve 42, and the lower end surface of the wall body 1 is tightly pressed with the upper surface of the supporting frame 53;

D: the verticality between the front surface of the wall body 1 and the upper surface of the base 2 is adjusted by utilizing a swinging structure 51 in the position adjusting mechanism 5;

e: the levelness of the upper surface of the wall body 1 and the upper surface of the base 2 is adjusted by utilizing a moving structure 52 in the position adjusting mechanism 5;

F: cement is poured into a gap below the supporting frame 53, and the supporting frame 53 is fixed in position after the cement is solidified, so that the fixing of the wall body 1 is completed.

The invention utilizes the keel inner sleeve and the keel inner sleeve which can move along the radial direction in the accommodating cavity to mount the fixed keel, increases the movable range of the keel sleeve to a circular area on the premise of ensuring good fixing of the fixed keel, and simultaneously realizes adjustment of position and angle, thereby ensuring that the fixed keel can be stably fixed in the keel inner sleeve within a larger tolerance range so as to reduce construction difficulty. Furthermore, the invention further enhances the stability of connection through the joint action of the keel sleeves in a plurality of adjacent accommodating cavities by enabling the axes formed by the outer supporting shafts of the keel sleeves in the adjacent two accommodating cavities to form an included angle of 90 degrees. Because the direction of motion of the fossil fragments overcoat in the adjacent accommodation chamber is perpendicular, after a plurality of fixed fossil fragments get into corresponding fossil fragments endotheca respectively, receive the restriction of fixed fossil fragments, the fossil fragments endotheca of establishing at fixed fossil fragments surface and supporting tightly with fixed fossil fragments can't remove, simultaneously, receive the perpendicular influence of direction of motion of fossil fragments overcoat in the adjacent accommodation chamber, the wall body passes through fossil fragments endotheca and fossil fragments overcoat and the position locking of each fixed fossil fragments, can't remove to arbitrary direction, thereby effectively guaranteed the quick locking of wall body and fixed fossil fragments positional relationship.

Furthermore, the invention also uses the position adjusting mechanism to adjust the angles of the wall body in the front-back direction and the left-right direction on the horizontal plane, thereby realizing the adjustment of the levelness and the verticality of the wall body; in the swing structure, the arc-shaped sliding rail is matched with the arc-shaped sliding rail groove on the supporting frame, and the worm with the self-locking function and the turbine are used as driving mechanisms, so that the adjustment of the wall perpendicularity can be realized.

Furthermore, the invention also utilizes the sliding connection of the moving block and the supporting frame in the moving structure to adjust the height of the right end of the supporting frame; the sliding rail is matched with the base to be hinged, the driving screw is used as a driving mechanism, and the levelness adjustment of the wall body on the horizontal plane is realized through the supporting frame.

Drawings

FIG. 1 is a schematic view of a green energy-saving fabricated building wall component structure according to the present invention;

FIG. 2 is a schematic view of the internal structure of a green energy-saving fabricated building wall component according to the present invention;

FIG. 3 is a schematic view of the keel sleeve according to the invention;

FIG. 4 is a schematic view of a position adjusting mechanism according to the present invention;

FIG. 5 is a schematic view of a mobile structure according to the present invention;

Fig. 6 is an enlarged schematic view of a sliding rail structure in the present invention.

Detailed Description

The invention is described in detail below with reference to the attached drawings and examples:

As shown in fig. 1 to 6, the green energy-saving assembled building wall member of the invention comprises a wall body 1, wherein a circular accommodating cavity 11 is arranged at one end, namely the lower end, of the wall body 1, which is close to a base 2, and a fixed keel 3 is inserted into the accommodating cavity 11, and the lower part of the fixed keel 3 is fixed with the base 2. In the existing construction technology, a wall body 1 is lifted to a certain height through lifting equipment and moves to the upper side of a base 2, the angle of the wall body 1 is manually adjusted to enable a containing cavity 11 to correspond to the position of a fixed keel 3, the lifting equipment moves downwards until the fixed keel 3 enters the containing cavity 11, the perpendicularity of the outer surface of the wall body 1 relative to the upper surface of the base 2 is detected through testing equipment, the front-back swinging angle of the wall body 1 is adjusted to enable the wall body 1 to be perpendicular to the base 2, then the wall body 1 is fixedly connected with the base 2 through a right-angle tool, cement is poured into the containing cavity 11 to enable the fixed keel 3 to be fixed with the wall body 1, at the moment, the wall body 1 is kept perpendicular to the base 2, the tool is removed after the cement is solidified, and the wall body 1 is assembled.

In the invention, a position adjusting mechanism 5 is arranged between a wall body 1 and a base 2, the upper end of the position adjusting mechanism 5 is connected with the lower surface of the wall body 1, and the lower end of the position adjusting mechanism is fixedly connected with the base; in this embodiment, position adjustment mechanism 5 includes the fossil fragments cover 4 of coaxial setting in the accommodation chamber 11, fossil fragments cover 4 cover is located fixed fossil fragments 3 outsides and fossil fragments cover 4 connects wall body 1, the guide through fossil fragments cover 4 has guaranteed that fixed fossil fragments 3 all can get into accommodation chamber 11 smoothly in bigger tolerance range, realize the fixed connection of base 2 and wall body 4, position adjustment mechanism 5 is used for driving wall body 1 on the horizontal plane fore-and-aft direction and left right direction's angular adjustment, carry out the adjustment of levelness and straightness to wall body 1 promptly, with the formation of assurance wall body 1 and base 2 is perpendicular.

In the invention, the keel sleeve 4 comprises a keel outer sleeve 41 coaxially arranged in the accommodating cavity 11, and the keel outer sleeve 41 is in sliding connection with the accommodating cavity 11 through outer support shafts 411 arranged on two sides, so that the keel outer sleeve 41 moves in the accommodating cavity 11 along the radial direction of the accommodating cavity 11; a keel inner sleeve 42 is coaxially inserted in the keel outer sleeve 41, and the keel inner sleeve 42 is in sliding connection with the keel outer sleeve 41 through inner support shafts 421 arranged on two sides, so that the keel inner sleeve 42 moves in the keel outer sleeve 41 along the radial direction of the accommodating cavity 11; the movement direction of the keel outer sleeve 41 and the keel inner sleeve 42 in the same accommodating cavity 11 is vertical; the connection mode of the accommodating cavity 11, the keel outer sleeve 41 and the keel inner sleeve 42 enlarges the movable range of the keel inner sleeve 42 and the keel inner sleeve 42 in the radial direction of the accommodating cavity 11, the outer supporting shaft 411 and the inner supporting shaft 421 are circular shafts, and meanwhile, the angle adjustment can be realized. The outer support shaft 411 of the keel sleeve 4 in the accommodating cavity 11 and the axis formed by the inner support shaft 421 form an included angle of 90 degrees, so that the movable range of the keel inner sleeve 42 can be increased to a circular area on the premise of ensuring good fixation of the fixed keel 3, and the fixed keel 3 can be stably fixed in the keel inner sleeve 42 within a larger tolerance range, so that the construction difficulty is reduced.

After the fixed keels 3 are inserted into the corresponding keel inner sleeves 42 in the accommodating cavities 11, the fixed keels 3 are abutted against the inner walls of the keel inner sleeves 42, so as to realize reliable connection between the wall body 1 and the fixed keels 3. Because the movement direction of the keel outer sleeve 41 in the adjacent accommodating cavity 11 is vertical, after a plurality of fixed keels 3 respectively enter the corresponding keel inner sleeves 42, the fixed keels 3 are limited, the keel inner sleeves 42 sleeved on the outer surfaces of the fixed keels 3 and propped against the fixed keels 3 cannot move, and meanwhile, the wall 1 is locked with the positions of the fixed keels 3 through the keel inner sleeves 42 and the keel outer sleeves 41 under the influence of the vertical movement direction of the keel outer sleeves 41 in the adjacent accommodating cavity 11 and cannot move towards any direction, so that the quick locking of the position relation of the wall 1 and the fixed keels 3 is effectively ensured.

In the invention, the angle adjustment of the wall body 1 in the front-back direction and the left-right direction on the horizontal plane is also carried out by utilizing the position adjustment mechanism 5, so that the adjustment of the levelness and the verticality of the wall body 1 is realized; the position adjusting mechanism 5 comprises a supporting frame 53, the upper surface of the supporting frame 53 is contacted with the lower end surface of the wall body 1, the left side of the lower end of the supporting frame 53 is connected with a swinging structure 51 in a sliding mode back and forth, and the swinging structure 51 is fixedly connected to one side of the base 2; the swinging structure 51 is used for adjusting the verticality between the front surface of the wall body 1 and the upper surface of the base 2; the right side of the lower end of the supporting frame 53 is connected with the moving structure 52 in a left-right sliding manner, the moving structure 52 is fixedly connected to the other side of the base 2, and the moving structure 52 is used for adjusting the levelness of the upper surface of the wall body 1 and the upper surface of the base 2; a through hole is formed in the middle of the supporting frame 53, and the fixing keel 3 penetrates through the supporting frame 53 through the through hole.

In the invention, the swing structure 51 comprises a stabilizer bar 513, one end of the stabilizer bar 513 is connected with an arc-shaped sliding rail 511 arranged on the base 2 in the front-back direction, and the sliding rail 511 is in sliding connection with the supporting frame 53 through an arc-shaped sliding rail groove 531 arranged on the corresponding side of the supporting frame 53 in the front-back direction, so that the verticality of the wall body 1 is adjusted; the sliding rail 511 is hinged with the base 2 through a hinge seat 514, a hinge shaft which is horizontally arranged and longitudinally arranged is arranged in the hinge seat 514, and the sliding rail 511 can rotate at a certain angle in the left-right direction through the hinge shaft.

In the invention, through the slide rail 511, the slide rail groove 531 and the support frame 53, the wall body 1 can rotate at a certain angle in the front-back direction on the horizontal plane, namely, the verticality adjustment is realized; the other end of the stabilizing rod 513 is connected with a turbine 512, a driving worm 515 matched with the turbine 512 is connected with a supporting frame 53, the driving worm 515 penetrates through the front end face and the rear end face of the supporting frame 53 and is rotationally connected with the supporting frame 53, the turbine 512 and the driving worm 515 are enabled to move relatively through the driving worm 515, and an arc-shaped track is formed along an arc-shaped sliding rail 511 arranged at one end of the stabilizing rod 513 during movement; and the cooperation of the worm 515 and the worm gear 512 can realize a self-locking function.

The moving structure 52 comprises a driving screw 523, one end of the driving screw 523 is connected with a moving block 522 through threaded fit, the other end of the driving screw 523 is rotatably connected with a screw supporting seat 521, the screw supporting seat 521 is fixed on the base 2, the upper surface of the moving block 522 is an arc surface matched with the sliding rail 511, the lower end of the moving block 522 is in sliding connection with the supporting frame 53, and the upper surface of the moving block 522 is an arc surface with high left and low right; the lower end surface of the supporting frame 53 contacted with the moving block 522 is provided with an arc-shaped groove matched with the upper surface of the moving block 522; the arc-shaped groove is an arc-shaped groove with high left and low right; the right end of the supporting frame 53 can be raised by driving the screw 523 to move the moving block 522 to the right along the screw axial direction; the driving screw 523 makes the moving block 522 move leftwards along the axial direction of the screw, so that the height of the right end of the supporting frame 53 can be reduced; since the slide rail 511 is hinged to the base 2 through the hinge seat 514, the levelness adjustment of the wall 1 on the horizontal plane can be realized through the support frame 53 by utilizing the rotation of the driving screw 523.

In the invention, the upper surface of the sliding rail is provided with a dovetail arc limiting strip along the circumferential direction; the sliding rail groove is an arc dovetail groove matched with the arc limiting strip. The design of the arc-shaped limiting strips and the arc-shaped dovetail grooves can ensure that the worm 515 and the turbine 512 can be always contacted in the process of changing the height of the right end of the driving support 53 of the moving structure 52 so as to ensure the position locking.

When the green energy-saving assembled building wall component is used for fixing an assembled building wall, the method sequentially comprises the following steps:

A: a position adjusting mechanism 5 is arranged above the base 2, so that a fixed keel 3 fixed above the base 2 is inserted into a corresponding through hole formed on the upper surface of the supporting frame 53;

B: moving the prefabricated wall body 1 to the position above the base 2 through hoisting equipment, and manually adjusting the angle of the wall body 1 to enable each fixed keel 3 to correspond to the position of the corresponding keel inner sleeve 42;

C: lowering the prefabricated wall body 1 through hoisting equipment, and adjusting the horizontal position and angle of the keel inner sleeves 42 in the accommodating cavity 11 in real time, so that each fixed keel 3 is inserted into the corresponding keel inner sleeve 42, and the lower end surface of the wall body 1 is tightly pressed with the upper surface of the supporting frame 53;

D: the verticality between the front surface of the wall body 1 and the upper surface of the base 2 is adjusted by utilizing a swinging structure 51 in the position adjusting mechanism 5;

e: the levelness of the upper surface of the wall body 1 and the upper surface of the base 2 is adjusted by utilizing a moving structure 52 in the position adjusting mechanism 5;

F: cement is poured into a gap below the supporting frame 53, and the supporting frame 53 is fixed in position after the cement is solidified, so that the fixing of the wall body 1 is completed.

Claims (10)

1. The green energy-saving assembled building wall component comprises a wall body, wherein the lower end of the wall body is provided with a containing cavity, a fixed keel is correspondingly inserted in the containing cavity, and the lower end of the fixed keel is fixed on a base; the method is characterized in that: a position adjusting mechanism is arranged between the wall body and the base, the upper end of the position adjusting mechanism is connected with the lower surface of the wall body, the lower end of the position adjusting mechanism is fixedly connected with the base, and a fixed keel is arranged in the position adjusting mechanism in a penetrating manner and is inserted into a corresponding keel sleeve which is arranged in a containing cavity of the wall body; the position adjusting mechanism drives the wall body to adjust angles in the front-back direction and the left-right direction on the horizontal plane.

2. A green energy efficient fabricated building wall component as claimed in claim 1, wherein: the keel sleeve comprises a keel sleeve coaxially arranged in the accommodating cavity, and the keel sleeve is in sliding connection with the accommodating cavity along the radial direction of the accommodating cavity through outer supporting shafts arranged on two sides of the keel sleeve; a keel inner sleeve is coaxially inserted in the keel outer sleeve, and the keel inner sleeve is in sliding connection with the keel outer sleeve along the radial direction of the accommodating cavity through inner supporting shafts arranged on two sides of the keel inner sleeve; the movement direction of the keel outer sleeve and the movement direction of the keel inner sleeve in the same accommodating cavity are vertical.

3. A green energy efficient fabricated building wall component as claimed in claim 2, wherein: the axes formed by the outer supporting shafts of the keel jackets in the adjacent accommodating cavities form an included angle of 90 degrees.

4. A green energy efficient fabricated building wall component as claimed in claim 1, wherein: the position adjusting mechanism comprises a support frame, the upper surface of the support frame is contacted with the lower end surface of the wall body, the left side of the lower end of the support frame is connected with a swinging structure in a sliding manner, and the swinging structure is fixedly connected to one side of the base; the swinging structure is used for adjusting the verticality between the front surface of the wall body and the upper surface of the base; the right side of the lower end of the support frame is connected with a moving structure in a sliding manner, the moving structure is fixedly connected to the other side of the base, and the moving structure is used for adjusting the levelness of the upper surface of the wall body and the upper surface of the base; the through hole has been seted up to support frame intermediate position, and fixed fossil fragments wear to locate the support frame through the through-hole.

5. A green energy efficient fabricated building wall component according to claim 4, wherein: the swing structure comprises a stabilizer bar, one end of the stabilizer bar is connected with an arc-shaped sliding rail arranged on the base, and the sliding rail is in sliding connection with the support frame through an arc-shaped sliding rail groove arranged on the corresponding side of the support frame; the sliding rail is hinged with the base through a hinge seat, and a hinge shaft which is arranged horizontally and front and back is arranged in the hinge seat; the turbine is connected to the stabilizer bar other end, and with turbine complex drive worm connection support frame, and drive worm wears to locate the terminal surface and rotate with the support frame and be connected around the support frame.

6. A green energy efficient fabricated building wall component according to claim 5, wherein: the movable structure comprises a driving screw, one end of the driving screw is connected with a movable block through threaded fit, the other end of the driving screw is rotationally connected with a screw supporting seat, the screw supporting seat is fixed on a base, the upper surface of the movable block is an arc-shaped surface matched with a sliding rail, the lower end of the movable block is in sliding connection with a supporting frame, and the left and right heights of the arc-shaped surface of the upper surface of the movable block are different.

7. A green energy efficient fabricated building wall component as defined in claim 6, wherein: the upper surface of the moving block is an arc surface with high left and low right; the lower end surface of the supporting frame contacted with the moving block is provided with an arc-shaped groove matched with the upper surface of the moving block; and the arc-shaped groove is an arc-shaped groove with high left and low right.

8. A green energy efficient fabricated building wall component according to claim 5, wherein: the upper surface of the sliding rail is provided with a dovetail arc limiting strip along the circumferential direction; the sliding rail groove is an arc dovetail groove matched with the arc limiting strip.

9. A green energy efficient fabricated building wall component as claimed in claim 2, wherein: the outer support shaft and the inner support shaft are round shafts.

10. A method of using a green energy efficient fabricated building wall element according to any one of claims 1 to 9, comprising the steps of, in order:

A: a position adjusting mechanism 5 is arranged above the base 2, so that a fixed keel 3 fixed above the base 2 is inserted into a corresponding through hole formed on the upper surface of the supporting frame 53;

B: moving the prefabricated wall body 1 to the position above the base 2 through hoisting equipment, and manually adjusting the angle of the wall body 1 to enable each fixed keel 3 to correspond to the position of the corresponding keel inner sleeve 42;

C: lowering the prefabricated wall body 1 through hoisting equipment, and adjusting the horizontal position and angle of the keel inner sleeves 42 in the accommodating cavity 11 in real time, so that each fixed keel 3 is inserted into the corresponding keel inner sleeve 42, and the lower end surface of the wall body 1 is tightly pressed with the upper surface of the supporting frame 53;

D: the verticality between the front surface of the wall body 1 and the upper surface of the base 2 is adjusted by utilizing a swinging structure 51 in the position adjusting mechanism 5;

e: the levelness of the upper surface of the wall body 1 and the upper surface of the base 2 is adjusted by utilizing a moving structure 52 in the position adjusting mechanism 5;

F: cement is poured into a gap below the supporting frame 53, and the supporting frame 53 is fixed in position after the cement is solidified, so that the fixing of the wall body 1 is completed.