CN118390790A - Construction strutting arrangement for building engineering - Google Patents

Abstract

The invention relates to the technical field of construction scaffolds, in particular to a construction supporting device for constructional engineering. The invention provides a construction supporting device for construction engineering, which can strengthen the installation stability of a buckle and avoid the slipping of the buckle caused by thermal expansion and cold contraction of an installation pipe. The construction supporting device comprises a mounting tube, a buckle, a sleeve, a supporting frame and the like, wherein the buckle is clamped on the outer side of the upper portion of the mounting tube, the sleeve is connected to the upper side of the mounting tube, and the supporting frame is connected to the lower portion of the mounting tube. According to the invention, the spiral spring is recovered by separating from the threaded rod when the connecting frame moves downwards, the rotating shaft is driven to rotate, and the rotating disc is driven to rotate, so that the rotating disc extrudes the first pushing frame to move outwards, the outer supporting piece is outwards propped to be in contact with the buckle, the installation stability of the buckle can be enhanced, and the effect of preventing the buckle from falling due to thermal expansion and cold contraction of the installation pipe is achieved.

Description

Construction strutting arrangement for building engineering

Technical Field

The invention relates to the technical field of construction scaffolds, in particular to a construction supporting device for constructional engineering.

Background

The construction scaffold for the building engineering is an important auxiliary facility on a construction site, and is mainly used for supporting a working platform, carrying constructors, tools and materials and carrying out construction operations at different heights.

The existing construction scaffold for the building engineering is formed by connecting and building steel pipes and fasteners, and is fixed in a construction area for use after the construction is completed, but the steel pipes can show the phenomenon of thermal expansion and cold contraction as a metal material, when the steel pipes shrink due to temperature reduction, the fasteners can easily slide off the steel pipes, so that the scaffold is inclined or even collapses, and the scaffold is dangerous.

Therefore, a construction supporting device for construction engineering, which can strengthen the installation stability of the buckle and avoid the falling of the buckle caused by thermal expansion and cold contraction of the installation pipe, is developed at present.

Disclosure of Invention

In order to overcome the defects that when the temperature is reduced and the steel pipe is contracted, the fastener is easy to slide off the steel pipe and the scaffold is inclined or even collapsed, and is dangerous in the prior construction scaffold for the construction engineering, the invention provides the construction supporting device for the construction engineering, which can strengthen the installation stability of the fastener and avoid the slide off of the fastener caused by thermal expansion and cold contraction of the installation pipe.

The technical implementation scheme of the invention is as follows: the utility model provides a construction strutting arrangement for building engineering, is including installation tube, buckle, sleeve pipe, support frame, support strengthening mechanism and installation stabilizing mean, and installation tube upper portion outside joint has the buckle, and the installation tube upside is connected with the sleeve pipe, and installation tube lower part is connected with the support frame, is equipped with the support strengthening mechanism that can strengthen support stability on the installation tube, still is equipped with the installation stabilizing mean that can strengthen buckle installation stability on the installation tube.

Optionally, support strengthening mechanism is including the lead screw, the knob, rotating member, the torsional spring, the stay cord, the slide bar, first spring, the connecting rod, link and locating part, install intraductal inboard slidingtype be connected with the lead screw, install intraductal downside rotation type be connected with the knob, knob and lead screw threaded connection, lead screw lower part rotation type be connected with a plurality of rotating members, be connected with the torsional spring between rotating member and the lead screw, all be connected with the stay cord on the rotating member, the inside slidingtype of lead screw is connected with the slide bar, the stay cord all passes the lead screw, the stay cord upside all is connected with the slide bar, be connected with first spring between slide bar and the lead screw, the slide bar upside is connected with the connecting rod, the connecting rod passes the lead screw, the connecting rod upside is connected with the link, install intraductal lower part is connected with the locating part, the locating part is located the link below, rotate the knob, make the lead screw downwardly moving, in making the rotating member insert, the lead screw downwardly moving, make connecting rod and link downwardly moving, after the connecting frame downwardly moving to contact with the locating part, the first spring receives the extrusion shrink, make the slide bar take place in the opposite rotation, the change shape in the lead screw, the rotating member is rotated and is stretched.

Optionally, the installation stabilizing mean is including mounting, the pivot, the scroll spring, the rolling disc, first pushing frame, outer support piece and threaded rod, upper portion is connected with a plurality of mounting in the installation tube, be connected with the pivot between the mounting, be connected with the scroll spring between both sides all and the pivot about the mounting, be connected with a plurality of rolling discs in the pivot, sliding type is connected with a plurality of first pushing frames between the rolling disc, all be connected with outer support piece on the first pushing frame, outer support piece all is connected with the installing tube contact, the pivot downside is connected with the threaded rod, threaded rod and linking frame contact cooperation, the scroll spring is in deformation state this moment, break away from the threaded rod when the linking frame moves down, make the scroll spring resume, drive the pivot rotatory, and then drive the rolling disc and rotate, make the first pushing frame of rolling disc extrusion outwards move, make outer support piece outwards strut with the buckle contact.

Optionally, the outer sides of the outer support pieces are all provided with anti-skid patterns.

Optionally, the device further comprises an adjusting mechanism, the adjusting mechanism comprises a rotating ring and limiting plates, the outer side of the lower portion of the mounting tube is rotatably connected with a plurality of rotating rings, the inner sides of the rotating rings are all connected with a plurality of limiting plates, the limiting plates all penetrate through the mounting tube, when the rotating piece is inserted into soil, the rotating rings at corresponding positions are rotatably adjusted according to the hardness of the soil, the limiting plates are located under the connecting frame, and when the connecting frame moves downwards, the connecting frame is limited through the limiting plates, so that the connecting frame stops moving downwards, and the rotating piece is rotated to be opened.

Optionally, still including solid fixed ring and elasticity screens piece, the installation pipe lower part outside is connected with a plurality of solid fixed rings, and gu fixed ring all is located adjacent rotation ring downside, all is connected with a plurality of elasticity screens piece on the solid fixed ring, and elasticity screens piece all cooperates with adjacent rotation ring joint, and elasticity screens piece on the solid fixed ring carries out the screens to the rotation ring, avoids rotation ring rotation.

Optionally, still including screens mechanism, screens mechanism is including the fixed plate, the second spring, the slider, first counterpoint spare, second counterpoint spare and second promote the frame, the installation pipe middle part inboard is connected with the fixed plate, the fixed plate downside is connected with the slider through the second spring, the pivot passes the slider, the slider is connected with the installation pipe slidingtype, the slider downside is connected with first counterpoint spare, the pivot lower part is connected with the second counterpoint spare, first counterpoint spare is located second counterpoint spare top, the link upside is connected with the second and promotes the frame, second promotes the frame and the slider extrusion cooperation, the second spring is in compression state this moment, the link moves down, drive the second and promote the frame and move down, make the second promote the frame break away from the slider, the second spring is kick-backed afterwards, make the slider move down, drive first counterpoint spare moves down, make first counterpoint spare and second counterpoint spare joint cooperation.

Optionally, the steel pipe clamping device further comprises a clamping mechanism, the clamping mechanism comprises elastic pieces, the inner side of the sleeve is connected with a plurality of elastic pieces, when the sleeve is matched with the steel pipe in a clamping mode, the elastic pieces are extruded by the steel pipe to deform, and the elastic pieces are enabled to be always pressed against the steel pipe through elasticity.

Optionally, the device further comprises an observation mechanism, the observation mechanism comprises a mounting sleeve and a rotating rod, the outer side of the lower part of the mounting pipe is connected with the mounting sleeve, the mounting sleeve is located below a fixing ring at the lowest side, the upper part of the mounting sleeve is rotationally connected with a plurality of rotating rods, the lower parts of the rotating rods are in contact with the mounting sleeve, after the mounting pipe is fixed on soil, whether the lower parts of the rotating rods rotate to be separated from the mounting sleeve is observed, and then whether the mounting pipe is in a vertical state is judged.

Optionally, gravity balls are arranged on the lower sides of the rotating rods.

The invention has the following advantages: 1. according to the invention, the spiral spring is recovered by separating from the threaded rod when the connecting frame moves downwards, the rotating shaft is driven to rotate, and the rotating disc is driven to rotate, so that the rotating disc extrudes the first pushing frame to move outwards, the outer supporting piece is outwards propped to be in contact with the buckle, the installation stability of the buckle can be enhanced, and the effect of preventing the buckle from falling due to thermal expansion and cold contraction of the installation pipe is achieved.

2. According to the invention, after the connecting frame moves downwards to be in contact with the limiting piece, the connecting frame stops moving downwards, the first spring is extruded and contracted, so that the sliding rod moves upwards relative to the screw rod, the pull rope is pulled to tighten, the rotating piece rotates to open and insert the rotating piece into soil, and the effect of enhancing the stability of the installation tube in the soil and avoiding the inclination of the installation tube during movement is achieved.

3. According to the invention, when the rotating member is inserted into the soil, the rotating ring at the corresponding position is rotated according to the hardness of the soil, so that the limiting plate is positioned under the connecting frame, and when the connecting frame moves downwards, the connecting frame is limited by the limiting plate, so that the connecting frame stops moving downwards, and the rotating member is rotated and unfolded, thereby achieving the effects of adjusting the rotating and unfolding depth of the rotating member in the soil and being convenient for adapting to the soil with different hardness.

4. According to the invention, the second pushing frame is driven to move downwards when the connecting frame moves downwards, so that the second pushing frame is separated from the sliding piece, then the second spring rebounds, so that the sliding piece moves downwards, the first alignment piece is driven to move downwards, and the first alignment piece is clamped and matched with the second alignment piece, so that the effects of clamping the rotating shaft and avoiding the outer supporting piece from being extruded and recovered are achieved.

5. According to the invention, when the sleeve is clamped and matched with the steel pipe, the steel pipe extrudes the elastic sheet to deform, and the elastic sheet always presses the steel pipe through elasticity, so that the effects of clamping the spliced steel pipe and enhancing the splicing stability are achieved.

6. According to the invention, after the installation pipe is fixed on the soil, whether the lower part of the rotating rod rotates under the action of the gravity ball to be separated from the installation sleeve is observed, so that whether the installation pipe is in a vertical state is judged, and the effect of detecting whether the installation pipe is vertical and avoiding the installation pipe from tilting and collapsing is achieved.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a partial perspective sectional view of the present invention.

Fig. 3 is a cross-sectional view of a first perspective structure of the support reinforcing mechanism of the present invention.

Fig. 4 is an exploded view of a three-dimensional structure of the support reinforcing mechanism of the present invention.

Fig. 5 is a cross-sectional view of a second perspective structure of the support reinforcement mechanism of the present invention.

Fig. 6 is a perspective view of a sectional view of the installation stabilization mechanism of the present invention.

Fig. 7 is a schematic perspective view of a first part of the installation stabilizing mechanism of the present invention.

Fig. 8 is a schematic perspective view of a second part of the present invention for installing a stabilizing mechanism.

Fig. 9 is a schematic perspective view of a third part of the installation stabilizing mechanism of the present invention.

Fig. 10 is a partial perspective sectional view of the installation stabilizing mechanism of the present invention.

Fig. 11 is a perspective sectional view of the adjusting mechanism of the present invention.

Fig. 12 is a cross-sectional view of a first perspective of the detent mechanism of the present invention.

Fig. 13 is a sectional view showing a second three-dimensional structure of the detent mechanism of the present invention.

Fig. 14 is a schematic perspective view of a clamping mechanism according to the present invention.

Fig. 15 is a schematic perspective view of the observation mechanism of the present invention.

Meaning of reference numerals in the drawings: 1: mounting a pipe, 2: buckle, 3: sleeve, 4: support frame, 5: support strengthening mechanism, 50: screw rod, 501: knob, 51: rotating member, 52: torsion spring, 53: pull rope, 54: slide bar, 55: first spring, 56: connecting rod, 57: connecting frame, 58: limiting piece, 6: installing a stabilizing mechanism, 60: fixing piece, 61: rotating shaft, 62: spiral spring, 63: rotating disk, 64: first pushing frame, 65: outer strut, 66: threaded rod, 7: adjustment mechanism, 70: a rotating ring, 71: limiting plate, 72: fixing ring, 73: elastic clamping piece, 8: clamping mechanism, 80: fixing plate, 81: second spring, 82: slide, 821: first alignment member, 83: second alignment member, 84: second pushing frame, 9: clamping mechanism, 90: elastic sheet, 10: observation mechanism, 101: mounting sleeve, 102: and rotating the rod.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings, for the purpose of making the objects, technical solutions and advantages of the present invention more apparent. It is only stated that the terms of orientation such as up, down, left, right, front, back, inner, outer, etc. used in this document or the imminent present invention, are used only with reference to the drawings of the present invention, and are not meant to be limiting in any way.

The utility model provides a construction strutting arrangement for building engineering, as shown in fig. 1 and fig. 2, including installation tube 1, buckle 2, sleeve pipe 3, support frame 4, support strengthening mechanism 5 and installation stabilizing mean 6, installation tube 1 upper portion outside joint has buckle 2, and installation tube 1 upside is connected with sleeve pipe 3, and installation tube 1 lower part is connected with support frame 4, is equipped with on the installation tube 1 and supports strengthening mechanism 5, still is equipped with installation stabilizing mean 6 on the installation tube 1.

As shown in fig. 1-5, the supporting and reinforcing mechanism 5 comprises a screw rod 50, a knob 501, rotating members 51, torsion springs 52, pull ropes 53, sliding rods 54, first springs 55, connecting rods 56, connecting frames 57 and limiting members 58, wherein the screw rod 50 is connected to the inner side of the lower portion of the installation tube 1 in a sliding mode, the knob 501 is connected to the knob 501 in a rotating mode, two rotating members 51 are connected to the lower portion of the screw rod 50 in a rotating mode, torsion springs 52 are connected between the rotating members 51 and the screw rod 50, pull ropes 53 are connected to the rotating members 51 in a sliding mode, sliding rods 54 are connected to the inner side of the screw rod 50 in a sliding mode, the pull ropes 53 penetrate through the screw rod 50, the first springs 55 are connected between the sliding rods 54 and the screw rod 50, the connecting rods 56 penetrate through the screw rod 50, the connecting frames 57 are connected to the upper side of the connecting rods 56, the limiting members 58 are connected to the inner lower portion of the installation tube 1, and the limiting members 58 are located below the connecting frames 57.

As shown in fig. 1, fig. 2, fig. 6, fig. 7, fig. 8, fig. 9 and fig. 10, the installation stabilizing mechanism 6 comprises a fixing part 60, a rotating shaft 61, a spiral spring 62, rotating discs 63, first pushing frames 64, outer supporting parts 65 and threaded rods 66, three fixing parts 60 are connected to the inner upper portion of the installation tube 1, the rotating shaft 61 is rotatably connected between the fixing parts 60, the spiral spring 62 is connected between the upper side and the lower side of the fixing parts 60 and the rotating shaft 61, six rotating discs 63 are connected to the rotating shaft 61, six first pushing frames 64 are slidably connected between the rotating discs 63, the outer supporting parts 65 are connected to the first pushing frames 64, anti-slip threads are arranged on the outer sides of the outer supporting parts 65, so that stability of the buckle 2 is enhanced, the outer supporting parts 65 are contacted with the installation tube 1, the threaded rods 66 are connected to the lower side of the rotating shaft 61, and the threaded rods 66 are contacted and matched with the connecting frames 57, and at the moment, the spiral spring 62 is in a deformed state.

When the invention is used, firstly, the installation tube 1 and the steel tube are spliced into a scaffold through the buckle 2, the installation tube 1 and the steel tube are vertically spliced through the sleeve 3 so as to meet the height of building construction, the spliced scaffold is placed in a construction area, the support frame 4 is contacted with the ground, then the knob 501 is rotated, the screw rod 50 is downwards moved, the rotating piece 51 is inserted into the soil, the screw rod 50 is downwards moved, simultaneously, the sliding rod 54 is driven to downwards move, the connecting rod 56 and the connecting frame 57 are downwards moved, when the connecting frame 57 is downwards moved to be contacted with the limiting piece 58, the connecting frame 57 is stopped to downwards move, the first spring 55 is extruded and contracted, the sliding rod 54 is upwards moved relative to the screw rod 50, the pulling rope 53 is pulled to be tightened, the rotating piece 51 is rotated and opened to be inserted into the soil, the torsional spring 52 deforms, thereby the stability of installation tube 1 in soil is strengthened, the effect of the slope of installation tube 1 removal is avoided, when scaffold frame one side is the mountain, can transversely splice installation tube 1 in the one side that is close to the mountain, make support strengthening mechanism 5 on the installation tube 1 can insert the mountain in fixed, strengthen scaffold frame stability, break away from threaded rod 66 when link 57 moves down, make spiral spring 62 resume, drive pivot 61 rotatory, and then drive rotating disc 63 rotation, make rotating disc 63 extrusion first pushing frame 64 outwards remove, make outer support 65 outwards strut and buckle 2 contact, thereby the installation stability that can strengthen buckle 2, avoid buckle 2 to lead to the effect of landing because of installation tube 1 expend with heat and contract with cold.

As shown in fig. 1 and 11, the device further comprises an adjusting mechanism 7, the adjusting mechanism 7 comprises a rotating ring 70, limiting plates 71, fixing rings 72 and elastic clamping pieces 73, the outer side of the lower portion of the mounting tube 1 is rotatably connected with three rotating rings 70, the inner sides of the rotating rings 70 are respectively connected with three limiting plates 71, the limiting plates 71 respectively penetrate through the mounting tube 1, the outer sides of the lower portion of the mounting tube 1 are respectively connected with three fixing rings 72, the fixing rings 72 respectively are located on the lower sides of the adjacent rotating rings 70, the fixing rings 72 respectively are respectively connected with two elastic clamping pieces 73, and the elastic clamping pieces 73 respectively are matched with the adjacent rotating rings 70 in a clamping mode.

By using the adjusting mechanism 7 of the device, the depth of the rotating part 51 which is opened in the soil can be adjusted, when the rotating part 51 is inserted into the soil, the rotating ring 70 at the corresponding position is adjusted in a rotating way according to the hardness of the soil, so that the limiting plate 71 is positioned under the connecting frame 57, the elastic clamping piece 73 on the fixing ring 72 clamps the rotating ring 70, the rotating ring 70 is prevented from rotating, when the connecting frame 57 moves downwards, the connecting frame 57 is limited by the limiting plate 71, the connecting frame 57 stops moving downwards, and then the rotating part 51 is enabled to rotate and open, so that the depth of the rotating part 51 which is opened in the soil can be adjusted, and the effect of adapting to the soil with different hardness is achieved.

As shown in fig. 1,2, 12 and 13, the clamping mechanism 8 further comprises a clamping mechanism 8, the clamping mechanism 8 comprises a fixed plate 80, a second spring 81, a sliding piece 82, a first aligning piece 821, a second aligning piece 83 and a second pushing frame 84, the inner side of the middle part of the installation tube 1 is connected with the fixed plate 80, the lower side of the fixed plate 80 is connected with the sliding piece 82 through the second spring 81, the rotating shaft 61 penetrates through the sliding piece 82, the sliding piece 82 is connected with the installation tube 1 in a sliding mode, the lower side of the sliding piece 82 is connected with the first aligning piece 821, the lower part of the rotating shaft 61 is connected with the second aligning piece 83, the first aligning piece 821 is located above the second aligning piece 83, the upper side of the connecting frame 57 is connected with the second pushing frame 84, the second pushing frame 84 is in extrusion fit with the sliding piece 82, and at the moment, the second spring 81 is in a compressed state.

The clamping mechanism 8 of the device can clamp the rotating shaft 61, the connecting frame 57 moves downwards and drives the second pushing frame 84 to move downwards, so that the second pushing frame 84 is separated from the sliding piece 82, then the second spring 81 rebounds, so that the sliding piece 82 moves downwards, the first aligning piece 821 is driven to move downwards, the first aligning piece 821 is matched with the second aligning piece 83 in a clamping way, and therefore the rotating shaft 61 can be clamped, and the outer supporting piece 65 is prevented from being extruded and recovered.

As shown in fig. 1 and 14, the clamping mechanism 9 is further included, the clamping mechanism 9 includes an elastic sheet 90, and six elastic sheets 90 are connected to the inner side of the sleeve 3.

The clamping mechanism 9 of the device can clamp the spliced steel pipes, when the sleeve 3 is matched with the steel pipes in a clamping mode, the steel pipes are extruded to deform the elastic sheets 90, the elastic sheets 90 are enabled to always press the steel pipes through elasticity, and therefore the effect of clamping the spliced steel pipes and reinforcing the splicing stability is achieved.

As shown in fig. 1 and 15, the observation mechanism 10 is further included, the observation mechanism 10 includes a mounting sleeve 101 and a rotating rod 102, the outer side of the lower portion of the mounting tube 1 is connected with the mounting sleeve 101, the mounting sleeve 101 is located below the fixing ring 72 at the lowest side, the upper portion of the mounting sleeve 101 is rotatably connected with four rotating rods 102, gravity balls are arranged on the lower sides of the rotating rods 102, rotation is facilitated, and the lower portions of the rotating rods 102 are in contact with the mounting sleeve 101.

By using the observation mechanism 10 of the device, whether the installation tube 1 is in a vertical state can be judged, after the installation tube 1 is fixed on soil, whether the lower part of the rotating rod 102 rotates under the action of the gravity ball to be separated from the installation sleeve 101 is observed, and whether the installation tube 1 is in a vertical state is further judged, so that the effect of detecting whether the installation tube 1 is vertical and avoiding the inclination and collapse of the installation tube 1 is achieved.

While the present disclosure has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present disclosure as defined by the appended claims and their equivalents. The scope of the disclosure should, therefore, not be limited to the above-described embodiments, but should be determined not only by the following claims, but also by the equivalents of the following claims.

Claims (10)

1. The utility model provides a construction strutting arrangement for building engineering which characterized in that: including installation pipe (1), buckle (2), sleeve pipe (3), support frame (4), support strengthening mechanism (5) and installation stabilizing mean (6), installation pipe (1) upper portion outside joint has buckle (2), and installation pipe (1) upside is connected with sleeve pipe (3), and installation pipe (1) lower part is connected with support frame (4), is equipped with on installation pipe (1) and can strengthen support strengthening mean (5) of supporting stability, still is equipped with on installation pipe (1) and can strengthen buckle (2) installation stabilizing mean (6) of installing stability.

2. A construction support device for construction engineering according to claim 1, wherein: the support reinforcing mechanism (5) comprises a screw rod (50), a knob (501), a rotating piece (51), a torsion spring (52), a pull rope (53), a sliding rod (54), a first spring (55), a connecting rod (56), a connecting frame (57) and a limiting piece (58), wherein the screw rod (50) is connected to the inner side of the lower portion of the installation tube (1) in a sliding mode, the knob (501) is connected to the lower side of the installation tube (1) in a rotating mode, the knob (501) is connected with the screw rod (50) in a threaded mode, the rotating pieces (51) are connected with the screw rod (50) in a rotating mode, the torsion spring (52) is connected between the rotating pieces (51) and the screw rod (50), the pull ropes (53) are connected to the rotating pieces (51), the sliding rods (54) are connected to the inner side of the screw rod (50) in a sliding mode, the upper sides of the pull ropes (53) are connected to the sliding rods (54), the first springs (55) are connected between the sliding rods (54) and the screw rod (50), the connecting rods (56) penetrate the screw rod (50), the connecting rods (56) are connected to the upper sides of the connecting rods (56) to the connecting rods (50), the connecting rods (57) are connected to the inner side of the connecting frame (58), the limiting piece (58) is located below the connecting frame (57), the knob (501) is rotated, the screw rod (50) moves downwards, the rotating piece (51) is inserted into soil, the screw rod (50) moves downwards, meanwhile, the sliding rod (54) is driven to move downwards, the connecting rod (56) and the connecting frame (57) move downwards, after the connecting frame (57) moves downwards to be in contact with the limiting piece (58), the connecting frame (57) stops moving downwards, the first spring (55) is extruded and contracted, the sliding rod (54) moves upwards relative to the screw rod (50), the pulling rope (53) is pulled to tighten, the rotating piece (51) rotates to be opened and inserted into the soil, and the torsion spring (52) deforms.

3. A construction support device for construction engineering according to claim 2, wherein: the installation stabilizing mechanism (6) comprises a fixing part (60), a rotating shaft (61), a spiral spring (62), a rotating disc (63), a first pushing frame (64), an outer supporting part (65) and a threaded rod (66), wherein the upper part in the installation tube (1) is connected with a plurality of fixing parts (60), the rotating shaft (61) is rotatably connected between the fixing parts (60), the spiral spring (62) is connected between the upper side and the lower side of the fixing parts (60) and the rotating shaft (61), the rotating shaft (61) is connected with a plurality of rotating discs (63), a plurality of first pushing frames (64) are slidably connected between the rotating discs (63), the first pushing frames (64) are connected with the outer supporting part (65) and are contacted with the installation tube (1), the threaded rod (66) is connected to the lower side of the rotating shaft (61), the threaded rod (66) is matched with the connecting frame (57) in a contact mode, at the moment, the spiral spring (62) is in a deformed state, and the threaded rod (66) is separated from the connecting frame (57) when the connecting frame (57) moves downwards, so that the scroll spring (62) is restored to drive the rotating shaft (61) to rotate, thereby driving the rotating disc (63) to rotate, so that the rotating disc (63) extrudes the first pushing frame (64) to move outwards, so that the outer support (65) is outwards spread to be contacted with the buckle (2).

4. A construction support device for construction engineering according to claim 3, wherein: the outer sides of the outer supporting pieces (65) are provided with anti-skid patterns.

5. A construction support device for construction engineering according to claim 3, wherein: the device is characterized by further comprising an adjusting mechanism (7), wherein the adjusting mechanism (7) comprises a rotating ring (70) and a limiting plate (71), the outer side of the lower portion of the mounting tube (1) is rotatably connected with a plurality of rotating rings (70), the inner sides of the rotating rings (70) are respectively connected with a plurality of limiting plates (71), the limiting plates (71) penetrate through the mounting tube (1), when a rotating member (51) is inserted into soil, the rotating rings (70) at corresponding positions are rotatably adjusted according to the hardness of the soil, the limiting plates (71) are located under the connecting frame (57), and when the connecting frame (57) moves downwards, the connecting frame (57) is limited through the limiting plates (71), so that the connecting frame (57) stops moving downwards, and the rotating member (51) is enabled to rotate and open.

6. A construction supporting apparatus for a construction project according to claim 5, wherein: still including solid fixed ring (72) and elasticity screens piece (73), the installation tube (1) lower part outside is connected with a plurality of solid fixed rings (72), gu fixed ring (72) all are located adjacent rotation ring (70) downside, all be connected with a plurality of elasticity screens piece (73) on gu fixed ring (72), elasticity screens piece (73) all cooperates with adjacent rotation ring (70) joint, elasticity screens piece (73) on gu fixed ring (72) carry out the screens to rotation ring (70), avoid rotation ring (70) rotation.

7. A construction supporting apparatus for construction engineering according to claim 6, wherein: the device also comprises a clamping mechanism (8), the clamping mechanism (8) comprises a fixed plate (80), a second spring (81), a sliding part (82), a first aligning part (821), a second aligning part (83) and a second pushing frame (84), the inner side of the middle part of the mounting tube (1) is connected with the fixed plate (80), the lower side of the fixed plate (80) is connected with the sliding part (82) through the second spring (81), the rotating shaft (61) passes through the sliding part (82), the sliding part (82) is connected with the mounting tube (1) in a sliding way, the lower side of the sliding part (82) is connected with a first aligning part (821), the lower part of the rotating shaft (61) is connected with a second aligning part (83), the first aligning part (821) is positioned above the second aligning part (83), the upper side of the connecting frame (57) is connected with the second pushing frame (84), the second pushing frame (84) is matched with the sliding part (82) in an extrusion mode, the second spring (81) is in a compression state, the connecting frame (57) moves downwards, and simultaneously drives the second pushing frame (84) to move downwards, so that the second pushing frame (84) moves downwards along with the second pushing part (81) to rebound, and then the second pushing part (82) moves downwards along with the sliding part (81), so that the first alignment piece (821) is in clamping fit with the second alignment piece (83).

8. A construction supporting apparatus for construction engineering according to claim 7, wherein: still including fixture (9), fixture (9) are including elastic sheet (90), and sleeve pipe (3) inboard is connected with a plurality of elastic sheets (90), and when joining in marriage sleeve pipe (3) and steel pipe joint, steel pipe extrusion elastic sheet (90) take place deformation, make elastic sheet (90) compress tightly the steel pipe all the time through elasticity.

9. A construction support device for construction engineering according to claim 8, wherein: still including observation mechanism (10), observation mechanism (10) are including installation cover (101) and dwang (102), installation pipe (1) lower part outside is connected with installation cover (101), installation cover (101) are located the solid fixed ring (72) below of downside, installation cover (101) upper portion rotation is connected with a plurality of dwang (102), dwang (102) lower part all contacts with installation cover (101), installation pipe (1) are fixed on soil after, observe dwang (102) lower part and rotate and break away from installation cover (101), and then judge whether installation pipe (1) are vertical state.

10. A construction support device for construction engineering according to claim 9, wherein: the lower sides of the rotating rods (102) are provided with gravity balls.