CN119593580A - Auxiliary assembly for construction - Google Patents

Abstract

The application relates to auxiliary equipment for building construction, which relates to the field of building construction equipment and comprises rails and floor auxiliary construction equipment, wherein the rails are arranged parallel to a first direction, two rails are distributed side by side in the second direction, the floor auxiliary construction equipment is arranged two in the first direction, the floor auxiliary construction equipment comprises a travelling mechanism, the travelling mechanism comprises a main supporting plate and supporting components, the main supporting plate is arranged perpendicular to a third direction, two supporting components are correspondingly arranged between each rail and the main supporting plate, one supporting component is a front supporting component, the other supporting component is a rear supporting component, the two telescopic components are sequentially distributed in the first direction, one end of each telescopic component is fixedly connected to the main supporting plate, the other end of each telescopic component is provided with a first roller, the first roller is rotationally connected to the telescopic component around a first axis, and the first axis is arranged parallel to the second direction. The application has the effect of improving the construction efficiency.

Description

Auxiliary assembly for construction

Technical Field

The application relates to the field of building construction equipment, in particular to auxiliary equipment for building construction.

Background

In the field of building construction, floor construction is a key and complex procedure, and a traditional floor construction method generally depends on manually constructing templates, so that the method is low in efficiency and high in labor intensity.

In order to achieve efficient floor construction, the prior art approaches mainly involve the use of movable construction platforms and automated formwork systems. A common mobile construction platform is typically comprised of rails, travelling mechanisms and support assemblies that are movable along a predetermined path to perform construction operations at different locations.

In the related art, in the construction process, after one concrete pouring is completed, the concrete needs to be completely solidified, and after the condition of removing the formwork of the floor slab is achieved, the construction platform can be moved to the next floor slab to be constructed, so that the construction time is prolonged, and the construction efficiency is lower.

Disclosure of Invention

The application provides an auxiliary device for building construction, which can improve the construction efficiency.

The auxiliary equipment for building construction provided by the application adopts the following technical scheme:

An auxiliary device for building construction, comprising:

a track arranged parallel to the first direction, two of the tracks being arranged side by side in the second direction, an

Floor auxiliary construction equipment, in first direction, floor auxiliary construction equipment is equipped with two, floor auxiliary construction equipment includes:

running gear, running gear includes:

a main support plate disposed perpendicular to the third direction, and

The support assemblies are respectively and correspondingly arranged between each track and the main support plate, one of the two support assemblies is a front support assembly, and the other support assembly is a rear support assembly;

The support assembly comprises two telescopic pieces, the telescopic direction of each telescopic piece is parallel to a third direction, the two telescopic pieces are sequentially distributed in the first direction, one of the two telescopic pieces is a front telescopic piece, and the other telescopic piece is a rear telescopic piece;

One end of the telescopic piece is fixedly connected to the main supporting plate, a first roller is arranged at the other end of the telescopic piece, the first roller is rotationally connected to the telescopic piece around a first axis, the first axis is parallel to a second direction, and the first roller is positioned on the track so as to roll along the first direction on the track.

By adopting the technical scheme, during the maintenance period of one section of floor slab, the other section of floor slab can be simultaneously subjected to construction preparation, so that the construction period is shortened.

Optionally, the telescopic piece includes two tertiary hydro-cylinders, in the third direction, two tertiary hydro-cylinders connect gradually, two any one of tertiary hydro-cylinders fixed connection in the main support board, another one with first gyro wheel is connected.

Through adopting above-mentioned technical scheme, the design of connecting gradually of two tertiary hydro-cylinders makes the effective flexible scope of extensible member in the third direction bigger.

Optionally, an auxiliary lap assembly is further included, the auxiliary lap assembly including:

An auxiliary supporting plate positioned between the main supporting plate and the rail in a third direction, and having a loading gap formed therebetween in the third direction, the auxiliary supporting plate being disposed perpendicular to the third direction, and

The auxiliary supporting plate is connected with the main supporting plate along the second direction in a sliding way so as to enable the auxiliary supporting plate to be adjusted between a storage posture and a unfolding posture;

when the auxiliary supporting plate is in the storage posture, on the orthographic projection in the third direction, the orthographic projection of the main supporting plate covers the orthographic projection of the auxiliary supporting plate;

when the auxiliary supporting plate is in the unfolding posture, on the orthographic projection in the third direction, part or all of the orthographic projection of the auxiliary supporting plate is positioned outside the orthographic projection of the main supporting plate.

Through adopting above-mentioned technical scheme, auxiliary stay board can accomodate and expand as required to when coping with complicated construction environment, especially having stand or other barriers between the floor, can nimble adjustment position. In addition, the design of the material placing gap enables the material to be conveniently placed between the main support plate and the auxiliary support plate.

Optionally, the main support plate is correspondingly provided with a plurality of auxiliary lap joint assemblies at two sides of the first direction, and the auxiliary lap joint assemblies at each side of the main support plate are sequentially distributed in the first direction.

Through adopting above-mentioned technical scheme, can adjust auxiliary stay plate's position and quantity in a flexible way according to actual need to adapt to the stand of different intervals and arrangement.

Optionally, the device further comprises a connection assembly, the connection assembly comprising:

A rotating connecting rod rotatable about a third axis, the third axis being parallel to the third direction, and

The connecting seat is provided with a caulking groove for the rotary connecting rod to rotationally insert around a third axis;

the plurality of floor auxiliary construction equipment are arranged, and the plurality of floor auxiliary construction equipment are sequentially distributed in the second direction;

In the second direction, in the side that two floor auxiliary construction equipment are close to each other, fixedly connected with in the auxiliary stay board in one of them floor auxiliary construction equipment the connecting seat rotates in the auxiliary stay board in another floor auxiliary construction equipment and is connected with the rotation connecting rod.

By adopting the technical scheme, the plurality of floor auxiliary construction equipment can be connected and disconnected with each other in the second direction by the arrangement of the connecting component, and when two floor auxiliary construction equipment are close to each other, the rotating connecting rod of one equipment can be inserted into the connecting seat of the other equipment for connection, so that the stability of the whole system is improved. Under the condition of synchronous construction of multiple floorslabs side by side, the connecting mode can effectively avoid construction errors caused by relative displacement among equipment.

Optionally, in the third direction, the connection assembly is located on a side of the accessory support plate near the track.

Through adopting above-mentioned technical scheme, personnel can stand and rotate the operation to the rotation connecting rod in the coupling assembling subaerial, have improved the operation security.

Optionally, a supporting frame is arranged between the main supporting plate and the supporting component, the supporting frame comprises a transverse support, the transverse support is parallel to the second direction, the transverse support is fixedly connected to one side, close to the track, of the main supporting plate, and the telescopic piece in the supporting component is connected to the transverse support. .

By adopting the technical scheme, the transverse support improves the connection stability of the main support plate and the support assembly.

Optionally, the support frame further comprises a longitudinal support, the longitudinal support is parallel to the first direction, the longitudinal support is fixedly connected to one side of the transverse support, which is far away from the main support plate, and the telescopic piece in the support assembly is connected to the longitudinal support.

By adopting the technical scheme, the stability of connection of the main support plate and the support component is improved due to the arrangement of the longitudinal support.

Optionally, the transverse support and the longitudinal support are both i-steel.

By adopting the technical scheme, the rigidity and stability of the supporting structure are improved.

Optionally, a linear driving member is connected between the cross brace and the auxiliary supporting plate, and a driving direction of the linear driving member is parallel to the second direction, so as to drive the auxiliary supporting plate to move along the second direction.

Through adopting above-mentioned technical scheme, the accessory shoe board can be driven to switch between accomodating gesture and expansion gesture to the linear drive spare, has improved the simple operation nature of equipment.

In summary, the present application includes at least one of the following beneficial technical effects:

The two floor auxiliary construction equipment is designed to alternately advance, so that during the maintenance period of one section of floor, the other section of floor can be simultaneously subjected to construction preparation, and the construction period is shortened;

the arrangement of the connecting component improves the stability of the whole system, and ensures that the cooperative operation between the adjacent floor auxiliary construction equipment is more efficient and stable;

the arrangement of the transverse support and the longitudinal support improves the connection stability between the main support plate and the support assembly.

Drawings

FIG. 1 is a schematic view of a floor auxiliary construction device on a track according to an embodiment of the present application;

FIG. 2 is a schematic view of a single floor slab auxiliary construction apparatus according to an embodiment of the present application;

FIG. 3 is an enlarged view of portion A of FIG. 1;

FIG. 4 is a schematic view of an auxiliary lap assembly according to an embodiment of the present application;

FIG. 5 is an enlarged view of portion B of FIG. 4;

FIG. 6 is a schematic view of a connection assembly according to an embodiment of the present application;

FIG. 7 is a schematic view of a post-cast strip auxiliary construction device overlapping a track in an embodiment of the application;

FIG. 8 is an enlarged view of portion C of FIG. 7;

FIG. 9 is a schematic structural view of post-cast strip auxiliary construction equipment in an embodiment of the present application;

FIG. 10 is a schematic view of a guide holder according to an embodiment of the present application;

FIG. 11 is a schematic view of the hinge and adjustment assembly of an embodiment of the present application;

FIG. 12 is a schematic view of the structure of the guide assembly and the adjustment assembly in an embodiment of the present application;

FIG. 13 is a schematic view of a sliding support block according to an embodiment of the present application;

Fig. 14 is an enlarged view of a portion D in fig. 13;

fig. 15 is an enlarged view of a portion E in fig. 9.

Reference numerals indicate 01, track; A1, auxiliary construction equipment of a first floor; A2, auxiliary construction equipment of a second floor; the mechanical arm comprises a traveling mechanism, 11, a main supporting plate, 2, a supporting component, 2a, a front supporting component, 2b, a rear supporting component, 21, a telescopic component, 21a, a front telescopic component, 21b, a rear telescopic component, 211, a three-level oil cylinder, 211a, a three-level oil cylinder, 211b, a lower three-level oil cylinder, 22, a first roller, 221, a ring groove, 23, a movable seat, 24, a first motor, 3, a supporting frame, 31, a longitudinal support, 32, a transverse support, 33, a groove, 4, an auxiliary lap joint component, 41, an auxiliary supporting plate, 411, a setting gap, 42, a hanger rod, 421, an avoidance groove, 43, a second roller, 44, a linear driving component, 45, a vertical rod, 46, a diagonal support, 5, a connecting component, 51, a rotary connecting rod, 52, a connecting seat, 521, an embedding groove, 6, a traveling seat, 61, a rolling component, 611, a roller frame, 612, a third roller, 613, a second motor, 7, a supporting device, 71, a guide seat, 711, a guide chute, 7111, a horizontal section, 7112, a vertical section, 7113, a guide block, 7272, a second guide block, 7273, a guide groove, 7273, a guide groove, a 13, a guide groove, a 3, a vertical groove, a vertical supporting block, a 3, a vertical supporting block, a 3, a vertical supporting component, a lifting component, a 3, a lifting component, a lifting component, a lifting, a lifting, a, a lifting, a, a, pushing strips 931, a first wedge surface, 932, a limiting piece, 933, a third wedge surface, 94, a second extension spring, 10, a supporting block, 100, a base, 101, a first supporting driving component, 1011, a first linear motor, 1012, a first oil cylinder, 1013, a second oil cylinder, 1014, a first lifting block, 102, a second supporting driving component, 1021, a second linear motor, 1022, a third oil cylinder, 1023, a fourth oil cylinder, 1024 and a second lifting block.

Detailed Description

The application is described in further detail below with reference to fig. 1-15. For convenience of description, the application introduces azimuth words such as a first direction, a second direction and a third direction to form a three-dimensional reference direction, the azimuth words such as a first direction, a second direction and a third direction can be specifically shown by referring to the figure, wherein X represents the first direction, Y represents the second direction, Z represents the third direction, the first direction, the second direction and the third direction are perpendicular to each other, and the application refers to front and back, and the application is understood as that the front is front, the back is back, and the construction travelling direction is parallel to the first direction along the construction travelling direction of a track.

The embodiment of the application discloses auxiliary equipment for building construction. Referring to fig. 1, the auxiliary equipment for construction includes a track 01, floor auxiliary construction equipment, and post-cast strip auxiliary construction equipment, the track 01 being disposed parallel to a first direction, and two tracks 01 being distributed side by side in a second direction.

In the second direction, since there may be a row of columns between two adjacent floors, in order to avoid the columns, a plurality of auxiliary devices for building construction may be simultaneously placed in the second direction, so as to perform synchronous side-by-side construction of the multiple floors, and each auxiliary device for building construction is used for constructing the floor between two adjacent rows of columns.

Referring to fig. 1, 2 and 3, in a first direction, two floor auxiliary construction devices are provided, and the two floor auxiliary construction devices are constructed alternately in the first direction, wherein the floor auxiliary construction device comprises a travelling mechanism 1, and the travelling mechanism 1 comprises a main support plate 11 and a support assembly 2;

the main support plate 11 is arranged perpendicular to the third direction, and in the construction process, a formwork can be built on the main support plate 11, and concrete can be poured on the built formwork to form a floor slab;

In order to connect the support assembly 2, a support frame 3 is arranged on one side of the main support plate 11, which is close to the tracks 01, the support frame 3 comprises two longitudinal supports 31 and a plurality of transverse supports 32, the transverse supports 32 are fixedly connected to the bottom wall of the main support plate 11, the transverse supports 32 are parallel to the second direction, the transverse supports 32 are arranged at intervals in the first direction, the longitudinal supports 31 are parallel to the first direction, one longitudinal support 31 is respectively arranged on one side of each track 01, which is close to the main support plate 11, and the longitudinal supports 31 are fixedly connected to the transverse supports 32;

The support assembly 2 is connected between the track 01 and the main support plate 11, specifically, the support assembly 2 is connected between the track 01 and the longitudinal support 31, four support assemblies 2 are arranged on the main support plate 11, two support assemblies 2 are correspondingly distributed on each track 01, one of the two support assemblies 2 on the same track 01 is a front support assembly 2a, and the other support assembly is a rear support assembly 2b;

The support assembly 2 comprises two telescopic members 21, the telescopic directions of the telescopic members 21 are parallel to a third direction, the two telescopic members 21 are sequentially distributed in a first direction, one of the two telescopic members 21 is a front telescopic member 21a, the other telescopic member is a rear telescopic member 21b, and the front telescopic member 21a is positioned in front of the rear telescopic member 21b in the first direction;

The telescopic piece 21 comprises two three-stage oil cylinders 211, in the third direction, the two three-stage oil cylinders 211 are sequentially connected, one of the two three-stage oil cylinders 211 is an upper three-stage oil cylinder 211a, the other is a lower three-stage oil cylinder 211b, the cylinder body of the upper three-stage oil cylinder 211a is fixedly connected to the longitudinal support 31, the piston rod of the upper three-stage oil cylinder 211a is fixedly connected to the piston rod of the lower three-stage oil cylinder 211b, and the cylinder body of the lower three-stage oil cylinder 211b is positioned at the track 01;

In order to enable the telescopic piece 21 to slide along the track 01 more smoothly, one end of the telescopic piece 21 far away from the main support plate 11 is provided with a first roller 22 capable of rolling along the track 01, specifically, the peripheral wall of the first roller 22 is coaxially provided with a ring groove 221, the cross section of the track 01 is I-shaped, the top of the track 01 is positioned in the ring groove 221 so as to guide the first roller 22 to roll along the track 01 by the wall of the ring groove 221, in order to drive the first roller 22 to rotate, a cylinder body of the lower three-stage oil cylinder 211b is fixedly connected with a movable seat 23, the first roller 22 is rotatably connected with the movable seat 23 around a first axis, the first axis is parallel to a second direction, among a plurality of telescopic pieces 21 used for supporting the main support plate 11, the movable seat 23 on at least one telescopic piece 21 is fixedly connected with a first motor 24, and an output shaft of the first motor 24 is coaxially and fixedly connected with the first roller 22 so that the first roller 22 is driven by the first motor 24 to rotate, and the telescopic piece 21 and the main support plate 11 can move forwards along with the first roller 22.

In the process of carrying out floor construction along the first direction, two floor auxiliary construction equipment alternately advance, and the concrete process is:

The two floor auxiliary construction equipment respectively walk to the positions of a first roof to be constructed and a second roof to be constructed along the track 01, the first roof to be constructed is positioned behind the second roof to be constructed, a person can build a formwork support system on a main support plate 11 at the first roof to be constructed, and concrete can be poured and maintained after the building is completed;

In the process, if the maintenance of the first floor slab is completed, floor auxiliary construction equipment below the first floor slab to be constructed can be moved to a third floor slab to be constructed, namely, after the maintenance of the rear floor slab is completed, the rear floor auxiliary construction equipment needs to be moved to the front of the front floor auxiliary construction equipment, so that the alternate walking of the floor auxiliary construction equipment is realized;

For convenience of description, naming two floor auxiliary construction devices as a first floor auxiliary construction device A1 and a second floor auxiliary construction device A2 respectively, wherein the first floor auxiliary construction device A1 is floor auxiliary construction equipment below a floor after curing, and the second floor auxiliary construction device A2 is floor auxiliary construction equipment below a floor under construction, and the first floor auxiliary construction device A1 needs to be moved to the front of the second floor auxiliary construction device A2;

the alternate construction process of the floor auxiliary construction equipment comprises the following steps:

S1, in the second floor auxiliary construction equipment A2, a rear telescopic piece 21b in a rear supporting component 2b is shortened;

S2, the first floor auxiliary construction equipment A1 with the telescopic piece 21 in a shortened state moves forward until the first roller 22 on the rear telescopic piece 21b shortened in S1 is overlapped to the main support plate 11 in the first floor auxiliary construction equipment A1;

S3, in the second floor auxiliary construction equipment A2, the front telescopic piece 21a in the rear supporting component 2b is shortened;

S4, the first floor auxiliary construction equipment A1 moves forwards until the first roller 22 on the front telescopic piece 21a shortened in S3 is overlapped to the main support plate 11 in the first floor auxiliary construction equipment A1;

S5, the first floor auxiliary construction equipment A1 continues to move forwards until the rear telescopic piece 21b in the front support assembly 2a is shortened and overlapped to the main support plate 11 in the first floor auxiliary construction equipment A1 in the second floor auxiliary construction equipment A2;

S6, in the second floor auxiliary construction equipment A2, the front telescopic piece 21a in the front support assembly 2a is shortened, the first floor auxiliary construction equipment A1 continues to move forward, and in the process, the second floor auxiliary construction equipment A2 rolls along the main support plate 11 in the first floor auxiliary construction equipment A1, so that the first roller 22 in the second floor auxiliary construction equipment A2 rolls, but the main support plate 11 in the second floor auxiliary construction equipment A2 is static compared with a floor slab under construction, until the rear telescopic piece 21b in the rear support assembly 2b is separated from the main support plate 11 in the first floor auxiliary construction equipment A1 in the second floor auxiliary construction equipment A2;

s6, in the second floor auxiliary construction equipment A2, a rear telescopic piece 21b in the rear supporting component 2b stretches and is overlapped on the track 01;

And S7, the first floor auxiliary construction equipment A1 continues to move forward until all the telescopic pieces 21 in the second floor auxiliary construction equipment A2 extend and overlap the track 01, so that the alternate moving forward of the two floor auxiliary construction equipment can be completed.

Referring to fig. 4 and 5, in some embodiments of the present application, the auxiliary lap joint assembly 4 is further included, a plurality of auxiliary lap joint assemblies 4 are correspondingly disposed on both sides of the main support plate 11 in the first direction, the plurality of auxiliary lap joint assemblies 4 on each side of the main support plate 11 are sequentially distributed in the first direction, and the auxiliary lap joint assemblies 4 include auxiliary support plates 41 and suspenders 42;

The auxiliary supporting plate 41 is arranged perpendicular to the third direction in which the auxiliary supporting plate 41 is located between the main supporting plate 11 and the rail 01, and a stock gap 411 is formed between the auxiliary supporting plate 41 and the main supporting plate 11;

The hanger rod 42 is slidably connected to the main support plate 11 along a second direction, specifically, an avoidance groove 421 is formed at one end of the hanger rod 42 near the main support plate 11, the avoidance groove 421 penetrates through the hanger rod 42 along the second direction, a second roller 43 rotatably connected to the hanger rod 42 around a second axis is arranged in the avoidance groove 421, the second axis is parallel to the first direction, and specifically, second rollers 43 are correspondingly arranged in two grooves 33 of the transverse support 32, and the second rollers 43 can roll along the transverse support 32 in the grooves 33;

To drive the boom 42 to move in the second direction, in some embodiments of the present application, a linear driving member 44 is further included and connected between the boom 42 and the cross-brace 32 to drive the boom 42 to move in the second direction, in this disclosure, the linear driving member 44 is a hydraulic cylinder, a cylinder body of the linear driving member 44 is fixedly connected to the cross-brace 32, and a piston rod of the linear driving member 44 is fixedly connected to the boom 42 to push the boom 42 to move in the second direction by the linear driving member 44;

The auxiliary supporting plate 41 is fixedly connected to the boom 42 and moves synchronously with the boom 42 along the second direction so that the auxiliary supporting plate 41 is adjusted between the storage posture and the supporting posture;

when the auxiliary supporting plate 41 is in the storage posture, on the orthographic projection in the third direction, the orthographic projection of the main supporting plate 11 completely covers the orthographic projection of the auxiliary supporting plate 41;

When the auxiliary supporting plate 41 is in the supporting posture, the front projection of the main supporting plate 11 covers part of the auxiliary supporting plate 41 on the front projection of the third direction, or the auxiliary supporting plate 41 is completely positioned outside the front projection of the main supporting plate 11, and when the auxiliary supporting plate 41 is in the supporting posture, the auxiliary supporting plate 41 can extend to between two adjacent upright posts distributed in the first direction to provide a supporting foundation for floor construction between the two adjacent upright posts in the same row;

In order to improve the stability of the support, in some embodiments of the present application, the auxiliary lap joint assembly 4 further includes a vertical rod 45 and an inclined strut 46, wherein a plurality of vertical rods 45 are fixedly connected to one side of the auxiliary supporting plate 41 close to the track 01, the vertical rods 45 are parallel to the third direction, inclined struts 46 are fixedly connected between each vertical rod 45 and the auxiliary supporting plate 41, the inclined struts 46 are located at the sides of the two sides of the main supporting plate 11, where the vertical rods are far away from each other, and the inclined struts 46, the vertical rods 45 and the auxiliary supporting plate 41 form a triangle structure, and preferably, the vertical rods 45 and the inclined struts 46 in the present disclosure are all i-steel.

Referring to fig. 6, in some embodiments of the present application, the present application further includes a connection assembly 5, wherein in a third direction, the connection assembly 5 is located at a side of the auxiliary support plate 41 near the track 01, the connection assembly 5 includes a rotation connection rod 51 and a connection seat 52, the rotation connection rod 51 can rotate around a third axis, and the third axis is parallel to the third direction;

In the second direction, in the side where two floor auxiliary construction equipment are close to each other, a connecting seat 52 is fixedly connected to the auxiliary support plate 41 in one floor auxiliary construction equipment, a rotary connecting rod 51 is rotatably connected to the auxiliary support plate 41 in the other floor auxiliary construction equipment, the rotary connecting rod 51 can rotate around a third axis along the auxiliary support plate 41, and in the second direction, the auxiliary support plates 41 in the two adjacent floor auxiliary construction equipment can be connected through a connecting assembly 5.

Referring to fig. 7 and 8, in some embodiments of the present application, a post-cast strip auxiliary construction apparatus is further included, the post-cast strip auxiliary construction apparatus being located behind the floor auxiliary construction apparatus, the post-cast strip auxiliary construction apparatus including a traveling seat 6 and a supporting device 7;

in order to facilitate the walking seat 6 to walk along the first direction, a rolling assembly 61 is arranged between the walking seat 6 and the track 01, the rolling assembly 61 comprises a roller frame 611 and a third roller 612, the roller frame 611 is fixedly connected with the walking seat 6, the third roller 612 is rotationally connected with the roller frame 611 through a fourth rotating shaft, the fourth rotating shaft is parallel to the second direction, the third roller 612 is consistent with the first roller 22 in shape, the third roller 612 is lapped on the track 01 and can roll along the track 01, so that the walking seat 6 can walk along the track 01 through the rolling assembly 61;

In some embodiments, the walking seat 6 is connected to each track 01 through two rolling assemblies 61, the two rolling assemblies 61 on each track 01 are distributed at intervals in a first direction, so that the walking seat 6 can move forward along the track 01 more stably through the rolling assemblies 61, at least one rolling assembly 61 is provided with a second motor 613 to drive a third roller 612 to rotate along the roller frame 611, specifically, the second motor 613 is a servo motor, a casing of the second motor 613 is fixedly connected to the roller frame 611, and an output shaft of the second motor 613 is coaxially and fixedly connected to the third roller 612, so that the second motor 613 drives the third roller 612 to rotate along the roller frame 611, and automatic walking of the walking seat 6 along the track 01 is realized.

Referring to fig. 9, 10 and 11, the walking seat 6 is provided with a plurality of supporting devices 7, and the supporting devices 7 are arranged at intervals in the second direction, wherein the supporting devices 7 comprise a guide seat 71 provided with a guide chute 711, a sliding supporting block 72 provided with a connecting side 721 and a hinge 73 provided with two connecting sheets 731;

The guide seat 71 is fixedly connected to the walking seat 6, the cross section of the guide chute 711 is T-shaped, the guide chute 711 comprises a horizontal section 7111, a vertical section 7112 and an arc section 7113, the horizontal section 7111 is parallel to the second direction, the vertical section 7112 is parallel to the third direction, one end of the arc section 7113 is communicated with the horizontal section 7111, the other end of the arc section 7113 is communicated with the vertical section 7112, and the arc section 7113 is in smooth transitional connection with the horizontal section 7111 and the vertical section 7112, so that the guide chute 711 is in an L-shaped groove structure with an arc angle formed by the communication of the horizontal section 7111, the arc section 7113 and the horizontal section 7111, an L-shaped sliding path with the arc angle can be formed along the trend of the guide chute 711, and the sliding support block 72 can move along the guide chute 711;

In order to enable the sliding support block 72 to move along the guide chute 711, a sliding piece 74 is connected to one side of the sliding support block 72, in the present disclosure, the sliding support block 72 and the guide seat 71 are sequentially distributed in a first direction, and the sliding support block 72 and the sliding piece 74 are also sequentially distributed in the first direction, wherein the sliding piece 74 is in a cylindrical step shaft shape, and the sliding piece 74 is adaptively positioned in the guide chute 711 and can walk along the trend of the guide chute 711 under the guiding action of the wall of the guide chute 711;

When the sliding support blocks 72 are positioned on the vertical section 7112, in the second direction, the connecting side 721 is positioned on one side of the sliding support block 72 close to the horizontal section 7111, a plurality of sliding support blocks 72 are sequentially distributed along the trend of the guide chute 711, a hinge 73 is connected between the connecting sides 721 of two adjacent sliding support blocks 72, two connecting pieces 731 of the hinge 73 are respectively and fixedly connected with the connecting side 721 of one sliding support block 72 through screws, and the connecting pieces 731 in the hinge 73 are hinged, and the hinge axis is parallel to the first direction so as to realize relative rotation between the two adjacent sliding support blocks 72;

in the operation process, a plurality of sliding support blocks 72 are pushed to move along the trend of a guide chute 711, after the sliding support blocks 72 are pushed upwards to be separated from the guide seats 71, the sliding support blocks 72 are pushed upwards continuously, the sliding support blocks 72 can prop a bottom template for a post-cast strip to be supported, after the bottom template of the post-cast strip to be supported is supported, concrete can be poured on the bottom template to form the post-cast strip, and a plurality of supporting devices are used for supporting the bottom template.

Referring to fig. 11, in order to ensure smoothness of sliding of the sliding support block 72 along the guide seat 71, to prevent the sliding support block 72 from being stuck, an adjusting assembly 8 is further provided between the sliding member 74 and the sliding support block 72, and the adjusting assembly 8 includes a shaking post 81, a drop-preventing disc 82, and a plurality of elastic members 83;

The shaking column 81 is coaxially and fixedly connected to the sliding piece 74, a through hole 722 for inserting the shaking column 81 is formed in the sliding supporting block 72, and the inner diameter of the through hole 722 is larger than the diameter of the shaking column 81 so that the shaking column 81 can shake in the through hole 722 along a plane perpendicular to the first direction;

in the first direction, the sliding support block 72 is provided with a movable hole 723 at one side of the through hole 722 far away from the sliding part 74, the inner diameter of the movable hole 723 is larger than the inner diameter of the through hole 722, one end of the shaking column 81 far away from the sliding part 74 is fixedly connected with the anti-falling disc 82 coaxially, the outer diameter of the anti-falling disc 82 is larger than the diameter of the through hole 722 and smaller than the inner diameter of the movable hole 723, so that the anti-falling disc 82 can shake along a plane perpendicular to the first direction on the premise of not separating from the movable hole 723;

The sliding support block 72 is close to the wall surface of the guide seat 71 and is provided with an avoidance annular groove 724 which is coaxial with the annular groove 221, the avoidance annular groove 724 is communicated with the perforation 722, the inner diameter of the avoidance annular groove 724 is larger than that of the perforation 722, the elastic pieces 83 are located in the avoidance annular groove 724, a plurality of elastic pieces 83 are uniformly distributed around the circumference of the avoidance annular groove 724, the expansion and contraction direction of the elastic pieces 83 is parallel to the diameter direction of the avoidance annular groove 724, one end of each elastic piece 21 is fixedly connected with the shaking column 81, the other end of each elastic piece is in contact with the inner wall of the avoidance annular groove 724, the elastic pieces 83 can be any one of elastic pieces such as elastic sheets, compression springs or elastic columns, and when the shaking column 81 is coaxial with the perforation 722, the elastic pieces 83 store elasticity generated by deformation.

Referring to fig. 12, in some embodiments of the present application, the present application further includes a guide assembly 84, where the guide assembly 84 includes an inner ring guide bar 841 and an outer ring guide bar 842, both of which are fixedly connected to the guide seat 71, along a running track of the sliding support block 72 on the guide seat 71, the inner ring guide bar 841 is located at a 90 ° angle side of the L-shaped track formed by the track, and the outer ring guide bar 842 is located at a 270 ° angle side of the L-shaped track formed by the track, that is, the sliding support block 72 is sandwiched between the outer ring guide bar 842 and the inner ring guide bar 841, so as to perform deviation rectification limiting on the running of the sliding support block 72 along the guide seat 71;

The inner ring guide bar 841 and the outer ring guide bar 842 each have a horizontal bar parallel to the first direction, and the inner ring guide bar 841 and the outer ring guide bar 842 each have a vertical bar parallel to the third direction; when the sliding support block 72 is positioned at the vertical section 7112 of the guide chute 711, the two sides are respectively contacted with one vertical bar so as to guide the movement of the sliding support block 72 along the third direction by the vertical bar;

The inner ring guiding strip 841 and the outer ring guiding strip 842 are provided with curved strips, one end of each curved strip is in smooth transition connection with the horizontal strip, the other end of each curved strip is in smooth transition connection with the vertical strip, and when the sliding supporting block 72 passes through the arc section 7113 of the guiding chute 711, the sliding supporting block 72 is positioned between the two curved strips;

Regarding the curvature of the curved bar, a simulation design can be made according to the motion track of the sliding support block 72, so as to design the limiting curvature required by the movement of the sliding support block 72 along the guiding chute 711, or the curved bar can be circular arc-shaped, and a gap is left between the sliding support block 72 and the curved bar, so as to realize the free movement of the sliding support block 72, and finally the sliding support block enters between the two vertical bars under the guidance of the curved bar and the vertical bar, and the two ways can be adopted, so that the disclosure is not repeated here.

Referring to fig. 13 and 14, in order to prevent the sliding support block 72 from rotating toward the connection side 721 of the sliding support block 72 after being separated from the end of the guide assembly 84 away from the traveling block 6, in some embodiments of the present application, a plug assembly 9 is further included, the plug assembly 9 including a plug rod 91 having a plug end 911, and further including a first compression spring 92, a push bar 93, and a second tension spring 94;

For convenience of description, one of the two adjacent sliding support blocks 72 is named as a first sliding support block 72a, and the other one is named as a second sliding support block 72b, when the two adjacent sliding support blocks 72 are positioned on the vertical section 7112 of the guide seat 71, in the third direction, the sliding support block 72 close to the horizontal section 7111 of the guide seat 71 is the first sliding support block 72a, and the sliding support block 72 far from the horizontal section 7111 of the guide seat 71 is the second sliding support block 72b;

The sliding support block 72 is provided with a splicing groove 725, when the sliding support block 72 is positioned on the vertical section 7112 of the guide seat 71, the splicing groove 725 is positioned on one side of the sliding support block 72 close to the circular arc section 7113 of the guide seat 71, the groove depth direction of the splicing groove 725 is parallel to a second direction, when the sliding support block 72 is positioned on the horizontal section 7111 of the guide chute 711, the second direction is parallel to a second direction, and when the sliding support block 72 is positioned on the vertical section 7112 of the guide chute 711, the second direction is parallel to a third direction;

The inserting connection rod 91 is located in the inserting groove 725 and is parallel to the second direction, and the inserting connection rod 91 can slide in the inserting groove 725 along the second direction, so that the inserting connection rod 91 can be adjusted between an unlocking posture and a locking posture;

when the inserting and connecting rod 91 is in the unlocking state, the inserting and connecting rod 91 is completely positioned in the inserting and connecting groove 725, and the first compression spring 92 is in a compressed state;

when the inserting rod 91 is in the locking state, one end of the inserting rod 91 is positioned in the inserting groove 725, and the inserting end 911 of the inserting rod 91 penetrates out of the sliding supporting block 72;

The first compression spring 92 is a compression spring, the expansion and contraction direction of the first compression spring 92 is parallel to the second direction, the first compression spring 92 is positioned in the inserting groove 725, one end of the first compression spring 92 is fixedly connected with the sliding support block 72, and the other end of the first compression spring 92 is fixedly connected with the inserting rod 91;

In the second direction, a locking groove 726 is formed in a wall surface of the sliding support block 72 away from the insertion end 911, the locking groove 726 is used for allowing the insertion rod 91 on the other sliding support block 72 to be inserted in the second direction, when the insertion rod 91 on the second sliding support block 72b is inserted into the locking groove 726 on the first sliding support block 72a in the two adjacent sliding support blocks 72, the two sliding support blocks 72 are fixed, the two sliding support blocks 72 cannot rotate along the hinge 73, and when the insertion rod 91 on the second sliding support block 72b is pulled out from the locking groove 726 on the first sliding support block 72a, the two sliding support blocks 72 are unlocked, and the two sliding support blocks 72 can rotate along the hinge 73.

Referring to fig. 13 and 14, in order to prevent the plugging rod 91 from being separated from the plugging slot 725 during the sliding of the plugging rod 91 along the plugging slot 725, a stopper plate 912 is fixedly connected to one end of the plugging rod 91 adjacent to the first compression spring 92, the outer ring contour of the stopper plate 912 is located at the outer ring contour of the plugging rod 91 on the front projection of the second direction, a sliding support block 72 is formed at the outer periphery of the plugging slot 725 in a stopper groove 727 matching with the stopper plate 912, a stopper surface 7271 is formed at one end of the stopper groove 727 adjacent to the plugging slot 725, the stopper plate 912 can move in the second direction in the stopper groove 727 to guide the movement of the stopper plate 912 in the second direction by the wall of the stopper groove 727, and when the stopper plate 912 contacts the stopper surface 7271, the plugging rod 91 can be prevented from continuing to slide outwards the plugging slot 725, and when the stopper plate 912 contacts the stopper surface 7271, the plugging rod 91 is in the locked state.

Referring to fig. 13 and 14, the sliding support block 72 is provided with a pushing groove 728 with a groove depth direction parallel to a third direction, when the sliding support block 72 is positioned on the vertical section 7112 of the guide seat 71, the pushing groove 728 is positioned on one side of the sliding support block 72 away from the arc section 7113 of the guide seat 71, when the sliding support block 72 is positioned on the vertical section 7112, the third direction is parallel to the second direction, and when the sliding support block 72 is positioned on the horizontal section 7111, the third direction is parallel to the third direction;

in the third direction, the pushing groove 728 penetrates through the side surface of the sliding support block 72, which is far away from the self-connecting side 721, and in the second direction, the pushing groove 728 penetrates through the side surface of the sliding support block 72, which is far away from the self-inserting groove 725;

When the pushing strip 93 is in the pushing posture, the pushing strip 93 is completely located in the pushing slot 728;

when the pushing strip 93 is in the exposed posture, one end of the pushing strip 93 away from the connecting side 721 of the sliding support block 72 extends out of the pushing groove 728;

The pushing strip 93 can elastically slide in the direction three, specifically, a limit groove 729 communicated with the pushing groove 728 is formed in the sliding support block 72, in the direction three, the limit groove 729 is located at one side of the locking groove 726 away from the connecting side 721 of the sliding support block 72, the side wall of the pushing strip 93 is fixedly connected with an adaptive limit piece 932 extending into the limit groove 729, the limit piece 932 can move in the direction three in the sliding support block 72 under the guidance of the wall of the limit groove 729, the second tension spring 94 is located in the limit groove 729 and located at one side of the limit piece 932 away from the connecting side 721 of the sliding support block 72, the expansion direction of the second tension spring 94 is parallel to the direction three, one end of the second tension spring 94 is fixedly connected to the wall of the limit groove 729, the other end of the second tension spring 94 is fixedly connected to the limit piece 932, when the pushing strip 93 is in the pushing posture, the second tension spring 94 is in the recoverable deformation state, and the second tension spring 94 has a force for pulling the pushing strip 93 to move from the connecting side 721 of the sliding support block 72 towards the direction of the locking groove 726;

The pushing strip 93 is formed with a first wedge surface 931 at one end thereof near the connection side 721 of the sliding support block 72, the first wedge surface 931 being inclined toward the connection side 721 of the sliding support block 72 in the direction from the first compression spring 92 to the socket rod 91 connected to the first compression spring 92, a second wedge surface 913 being formed at one end of the socket rod 91 remote from the first compression spring 92, the second wedge surface 913 being parallel to the first wedge surface 931;

When the pushing strip 93 is in the exposed posture, the first wedge-shaped surface 931 is in contact with the second wedge-shaped surface 913, and the end of the plugging rod 91, which is far away from the first compression spring 92, is inserted into the pushing groove 728 of the other sliding supporting block 72 and simultaneously inserted into the locking groove 726, so that the two adjacent sliding supporting blocks 72 can be prevented from rotating along the hinge 73;

In the process that the pushing strip 93 moves from the exposed posture to the pushing posture, when the pushing strip 93 moves towards the connection side 721 and the first wedge-shaped surface 931 contacts with the second wedge-shaped surface 913, the inserting rod 91 on the other sliding support block 72 is pushed to move towards one side of the first compression spring 92 so as to unlock the inserting rod 91 from the locking posture to the unlocking posture, after the inserting rod 91 is in the unlocking posture, the first wedge-shaped surface 931 and the second wedge-shaped surface 913 are separated, and the two adjacent sliding support blocks 72 can rotate along the hinge 73;

When the sliding support blocks 72 are located between the inner ring guiding bars 841 and the outer ring guiding bars 842, the guiding component 84 can limit the pushing bars 93 in the pushing grooves 728, so that two adjacent sliding support blocks 72 can rotate along the hinges 73, and when the sliding support blocks 72 move to be separated from the guiding component 84, the pushing bars 93 move from the pushing posture to the exposed posture under the pushing of the second stretching springs 94.

Referring to fig. 13 and 14, in the process of moving the sliding support block 72 from the posture separated from the guiding component 84 to the guiding component 84 in the third direction, in order to facilitate the pushing of the pushing strip 93 to the connection side 721 of the sliding support block 72, in some embodiments of the present application, one end of the pushing strip 93 away from the connection side 721 is a third wedge surface 933, the third wedge surface 933 is parallel to the first wedge surface 931, when the pushing strip 93 is in the exposed posture, one end of the first wedge surface 931 is located in the pushing groove 728, and the other end is located outside the sliding support block 72, and when the sliding support block 72 moves to the third wedge surface 933 and the outer ring guiding strip 842, as the sliding support block 72 continues to move towards the side of the walking seat 6, the outer ring guiding strip 842 pushes the third wedge surface 933 towards the connection side 721 of the sliding support block 72, that is to push the pushing strip 93 towards the connection side 721 of the sliding support block 72, so that the exposed posture of the sliding support block 72 can be adjusted.

In the construction process, the height of the template for supporting the post-cast strip between the supporting devices 7 is limited, because the height of the supporting component 2 is at a lower height before the template is supported, the template can be pushed upwards along with the upward movement process of the pushing template, the template overlapping process can be performed under the condition that the supporting devices 7 are lower, and a person can work while standing on the ground, so that the work safety can be improved.

Referring to fig. 12 and 15, in order to facilitate pushing the sliding support block 72 to move along the third direction, in some embodiments of the present application, a driving part and a top support block 10 are further included, in the second direction, the driving part is located at one side of the vertical section 7112 near the horizontal section 7111, the driving part includes a base 100, a first top support driving assembly 101 and a second top support driving assembly 102, the base 100 is fixedly connected to the guide seat 71, the first top support driving assembly 101 includes a first linear motor 1011, a first cylinder 1012, a second cylinder 1013 and a first lifting block 1014, and the second top support driving assembly 102 includes a second linear motor 1021, a third cylinder 1022, a fourth cylinder 1023 and a second lifting block 1024;

the driving directions of the first linear motor 1011 and the second linear motor 1021 are parallel to the first direction, and the first linear motor 1011 and the second linear motor 1021 are fixedly connected to the base 100 through screws;

the driving directions of the first cylinder 1012 and the third cylinder 1022 are parallel to the third direction, and the driving directions of the second cylinder 1013 and the fourth cylinder 1023 are parallel to the second direction;

In the second direction, the first oil cylinder 1012 and the third oil cylinder 1022 are distributed at intervals, and the first oil cylinder 1012 is positioned at one side of the third oil cylinder 1022 close to the vertical section 7112, the cylinder body of the first oil cylinder 1012 is fixedly connected with the output part of the first linear motor 1011 so as to drive the first oil cylinder 1012 to move along the first direction by the first linear motor 1011, and the cylinder body of the third oil cylinder 1022 is fixedly connected with the output part of the second linear motor 1021 so as to drive the third oil cylinder 1022 to move along the first direction by the second linear motor 1021;

The cylinder body of the second cylinder 1013 is fixedly connected to the piston rod of the first cylinder 1012, and the first lifting block 1014 is fixedly connected to the piston rod of the second cylinder 1013;

in the third direction, the second oil cylinders 1013 and the fourth oil cylinders 1023 are distributed at intervals, and the second oil cylinders 1013 are positioned on one side of the fourth oil cylinders 1023 close to the horizontal section 7111, the cylinder body of the fourth oil cylinders 1023 is fixedly connected with the piston rod of the third oil cylinder 1022, and the second lifting blocks 1024 are fixedly connected with the piston rod of the fourth oil cylinders 1023;

The sliding support blocks 72 are fixedly and convexly provided with top support blocks 10 on the connecting sides 721, when the sliding support blocks 72 are positioned on the vertical sections 7112, insertion gaps are formed between the top support blocks 10 on two adjacent sliding support blocks 72 in the third direction, and the insertion gaps are used for inserting the first lifting blocks 1014 or the second lifting blocks 1024;

In operation, if the sliding support block 72 located in the vertical section 7112 is required to be driven in a direction away from the horizontal section 7111, only one of the top support blocks 10 is required to be supported by the second lifting block 1024, then the first lifting block 1014 is driven to move to a position of one of the top support blocks 10 located between the second lifting block 1024 and the horizontal section 7111 and support the top support block 10, then the second lifting block 1024 is removed to separate the second lifting block 1024 from the top support block 10, then the top support block 10 is driven by the first lifting block 1014 to move in a direction away from the horizontal section 7111, and then the top support block 10 is driven to move in a third direction away from the horizontal section 7111, and then the above-mentioned process is repeated until the sliding support block 72 is adjusted to a desired position.

The implementation principle of the auxiliary equipment for building construction is that the auxiliary construction equipment for building construction is positioned below a building slab to be poured, auxiliary support plates 41 on two sides are outwards moved to be between two upright posts distributed in a first direction, two adjacent auxiliary support plates 41 distributed in a second direction are fixed, after the mould is removed, the fixing between the two auxiliary support plates 41 is released, the auxiliary support plates 41 are retracted, and the building slab auxiliary construction equipment is walked below the next building slab to be poured;

After construction of two adjacent floorslabs is completed in the first direction, the post-cast strip auxiliary construction equipment is moved to the lower side of the post-cast strip to be poured along the track 01, a bottom formwork for supporting the post-cast strip is erected on the supporting device 7, the sliding supporting blocks 72 are driven by the first supporting driving assembly 101 and the second supporting driving assembly 102 to move upwards until the bottom formwork for supporting the post-cast strip is supported to a required height, and finally concrete is poured on the bottom formwork and maintained.

The above embodiments are not intended to limit the scope of the application, so that the equivalent changes of the structure, shape and principle of the application are covered by the scope of the application.

Claims (10)

1. An auxiliary device for construction, comprising:

A track (01), said track (01) being arranged parallel to the first direction, two of said tracks (01) being arranged side by side in the second direction, and

Floor auxiliary construction equipment, in first direction, floor auxiliary construction equipment is equipped with two, floor auxiliary construction equipment includes:

Running gear (1), running gear (1) includes:

a main support plate (11), the main support plate (11) being arranged perpendicular to the third direction, and

The support assemblies (2), two support assemblies (2) are correspondingly arranged between each track (01) and the main support plate (11), one of the two support assemblies (2) is a front support assembly (2 a), and the other support assembly is a rear support assembly (2 b);

The support assembly (2) comprises two telescopic pieces (21), the telescopic directions of the telescopic pieces (21) are parallel to a third direction, the two telescopic pieces (21) are sequentially distributed in a first direction, one of the two telescopic pieces (21) is a front telescopic piece (21 a), and the other telescopic piece is a rear telescopic piece (21 b);

One end of the telescopic piece (21) is fixedly connected to the main supporting plate (11), a first roller (22) is arranged at the other end of the telescopic piece, the first roller (22) is rotatably connected to the telescopic piece (21) around a first axis, the first axis is parallel to a second direction, and the first roller (22) is located on the track (01) so as to roll along the first direction on the track (01).

2. An auxiliary device for building construction according to claim 1, wherein the telescopic member (21) comprises two tertiary cylinders (211), and in the third direction, the two tertiary cylinders (211) are connected in sequence, one of the two tertiary cylinders (211) is fixedly connected to the main support plate (11), and the other is connected to the first roller (22).

3. An auxiliary device for building construction according to claim 2, further comprising an auxiliary overlap assembly (4), the auxiliary overlap assembly (4) comprising:

An auxiliary supporting plate (41), in a third direction, the auxiliary supporting plate (41) being located between the main supporting plate (11) and the rail (01), and a loading gap (411) being formed between the auxiliary supporting plate (41) and the main supporting plate (11) in the third direction, the auxiliary supporting plate (41) being arranged perpendicular to the third direction, and

A boom (42), the boom (42) being slidably connected to the main support plate (11) in a second direction, one end of the boom (42) being connected to the main support plate (11) and the other end being connected to the auxiliary support plate (41), the auxiliary support plate (41) being slidably connected to the main support plate (11) with the boom (42) in the second direction to adjust the auxiliary support plate (41) between a storage position and a deployment position;

when the auxiliary supporting plate (41) is in the storage posture, on the orthographic projection in the third direction, the orthographic projection of the main supporting plate (11) covers the orthographic projection of the auxiliary supporting plate (41);

When the auxiliary supporting plate (41) is in the unfolding attitude, on the orthographic projection of the third direction, part or all of the orthographic projection of the auxiliary supporting plate (41) is positioned outside the orthographic projection of the main supporting plate (11).

4. A building construction auxiliary device according to claim 3, wherein the main support plate (11) is provided with a plurality of auxiliary lap joint assemblies (4) correspondingly distributed on both sides of the first direction, and the auxiliary lap joint assemblies (4) on each side of the main support plate (11) are sequentially distributed in the first direction.

5. An auxiliary device for building construction according to claim 4, further comprising a connection assembly (5), the connection assembly (5) comprising:

A rotating connecting rod (51), the rotating connecting rod (51) being rotatable about a third axis, the third axis being parallel to the third direction, and

The connecting seat (52) is provided with a caulking groove (521) for the rotary connecting rod (51) to be inserted in a rotary mode around a third axis;

the plurality of floor auxiliary construction equipment are arranged, and the plurality of floor auxiliary construction equipment are sequentially distributed in the second direction;

In the second direction, in the side that two floor auxiliary construction equipment are close to each other, fixedly connected with on auxiliary stay board (41) in one of them floor auxiliary construction equipment connecting seat (52), be connected with on auxiliary stay board (41) in another floor auxiliary construction equipment rotation rotating connecting rod (51).

6. An auxiliary device for building construction according to claim 5, characterized in that in the third direction the connection assembly (5) is located on the side of the auxiliary support plate (41) close to the track (01).

7. An auxiliary device for building construction according to any of claims 5-6, characterized in that a supporting frame (3) is arranged between the main supporting plate (11) and the supporting component (2), the supporting frame (3) comprises a transverse brace (32), the transverse brace (32) is arranged parallel to the second direction, the transverse brace (32) is fixedly connected to one side of the main supporting plate (11) close to the track (01), and the telescopic piece (21) in the supporting component (2) is connected to the transverse brace (32).

8. An auxiliary device for building construction according to claim 7, wherein the supporting frame (3) further comprises a longitudinal support (31), the longitudinal support (31) is parallel to the first direction, the longitudinal support (31) is fixedly connected to one side of the transverse support (32) away from the main supporting plate (11), and the telescopic member (21) in the supporting assembly (2) is connected to the longitudinal support (31).

9. The auxiliary equipment for building construction according to claim 8, wherein the cross brace (32) and the longitudinal brace (31) are both i-steel.

10. An auxiliary device for building construction according to claim 9, wherein a linear driving member (44) is connected between the cross-brace (32) and the boom (42), the driving direction of the linear driving member (44) being parallel to the second direction for driving the boom (42) to move in the second direction.