CN112663933A - Automatic mounting method for fastener type steel pipe scaffold - Google Patents

Abstract

The invention discloses an automatic mounting method of a fastener type steel pipe scaffold, wherein a scaffold mounting robot used in the method comprises a rack, a traveling mechanism, a pipe embracing mechanism, a mounting plate, a steel pipe conveying mechanism and a scaffold assembling mechanism, wherein the scaffold assembling mechanism comprises a working box, a steel pipe clamp storage groove, a steel pipe and steel pipe clamp assembling groove, a steel pipe clamp hoisting mechanism, a steel pipe overturning mechanism, a steel pipe clamp fastening mechanism and the like. The steel pipe conveying mechanism is used for conveying steel pipes to the scaffold assembling mechanism, part of the steel pipes are horizontally inserted into the steel pipe clamps, part of the steel pipes need to be inserted into the steel pipe clamps after the steel pipe overturning mechanism, and the steel pipe clamp fastening mechanism is used for fastening each steel pipe. The method improves the installation efficiency of the scaffold.

Description

Automatic mounting method for fastener type steel pipe scaffold

Technical Field

The invention belongs to the technical field of scaffold installation, and particularly relates to an automatic installation method of a fastener type steel pipe scaffold.

Background

The scaffold is a working platform which is erected for ensuring that each construction process is smoothly carried out. According to the difference of materials, the scaffold can be divided into a wooden scaffold, a bamboo scaffold and a steel pipe scaffold. Among them, steel pipe scaffolds are most commonly used.

At present, to the buildding of scaffold frame, mainly still with the manual work buildding as leading, be about to wait to connect the steel pipe and carry out manual connection through the steel pipe connecting piece, this kind of mode of buildding not only takes trouble hard, and scaffold frame buildding is efficient moreover.

Disclosure of Invention

The invention aims to provide an automatic mounting method of a fastener type steel pipe scaffold, which improves the automation degree of scaffold building by means of a scaffold mounting robot and further improves the scaffold mounting efficiency.

In order to achieve the purpose, the invention adopts the following technical scheme:

a method for automatically installing a fastener-type steel pipe scaffold is characterized in that the installation of the fastener-type steel pipe scaffold is realized based on a scaffold installation robot; this scaffold installation robot includes:

the scaffold comprises a frame, a travelling mechanism, a pipe embracing mechanism, a mounting plate, a steel pipe conveying mechanism and a scaffold assembling mechanism;

the walking mechanism comprises a transverse moving mechanism and a longitudinal moving mechanism; the transverse movement mechanism and the longitudinal movement mechanism are both arranged on the rack and are respectively used for driving the rack to realize movement in a first direction and a second direction;

the first direction and the second direction are two directions which are vertical to each other in a horizontal plane;

the pipe embracing mechanism is arranged on the rack and is configured to be used for realizing the position fixation of the rack after running in place;

the mounting plate is positioned above the rack and extends along a first direction with the rack;

an installation plate lifting mechanism is arranged between the frame and the installation plate;

a lifting mechanism moving mechanism is arranged at the bottom of the mounting plate lifting mechanism, is mounted on the rack and is configured to drive the mounting plate lifting mechanism to move along a second direction;

the scaffold assembling mechanism and the steel pipe conveying mechanism are arranged on the mounting plate; the two steel pipe conveying mechanisms are respectively positioned on the opposite sides of the scaffold assembling mechanism in the first direction;

the steel pipe conveying mechanism is configured to convey steel pipes to the scaffold assembling mechanism;

the scaffold assembling mechanism comprises a working box, a steel pipe clamp storage groove, a steel pipe and steel pipe clamp assembling groove, a steel pipe clamp hoisting mechanism, a steel pipe overturning mechanism, a steel pipe clamp fastening mechanism and a fastening mechanism walking driving mechanism;

the working box is a square box body with an opening at one side, and the opening of the working box faces to the second direction;

two opposite side plates of the working box along the first direction are respectively provided with a steel pipe upper part feeding groove and a steel pipe lower part feeding groove; wherein, the steel pipe upper part feeding groove and the steel pipe lower part feeding groove are both positioned at the opening of the working box;

the upper steel pipe feeding grooves and the lower steel pipe feeding grooves on the two opposite side plates are respectively arranged in a one-to-one correspondence manner;

the feeding groove at the upper part of the steel pipe and the feeding groove at the lower part of the steel pipe are both U-shaped grooves;

the opening of the steel pipe upper feeding groove faces to the third direction, and the opening of the steel pipe lower feeding groove faces to the second direction; the third direction is a direction perpendicular to the horizontal plane, namely a vertical direction;

the steel pipe clamp storage groove is arranged in the working box and used for storing the steel pipe clamp;

the steel pipe clamp comprises a first steel pipe clamp and a second steel pipe clamp, and when the first steel pipe clamp and the second steel pipe clamp are combined to form the steel pipe clamp, steel pipe fixing holes for accommodating steel pipes are formed in multiple surfaces of the steel pipe clamp respectively;

the first steel pipe clamp and the second steel pipe clamp are arranged in pairs and in a split mode in the steel pipe clamp storage groove;

the steel pipe and steel pipe clamp assembling groove is positioned in the middle of the opening side of the working box and is arranged on the bottom plate of the working box;

the steel pipe and steel pipe clamp assembling groove comprises a fixed groove body and a movable groove body, wherein the movable groove body is provided with a movable groove body walking driving mechanism which is used for driving the movable groove body to move along a second direction;

the steel pipe clamp hoisting mechanism comprises a steel pipe clamp hoisting clamp and a three-axis motion driving mechanism;

the steel pipe clamp hoisting clamp is arranged on the three-axis motion driving mechanism;

the three-axis motion driving mechanism is used for driving the steel pipe clamp hoisting clamp to move along the first direction, the second direction and the third direction;

the steel pipe clamp hoisting clamp is used for sequentially taking out a first steel pipe clamp and a second steel pipe clamp from the steel pipe clamp storage groove, and correspondingly placing the taken-out first steel pipe clamp and the taken-out second steel pipe clamp in the fixed groove body and the movable groove body respectively;

the steel pipe turnover mechanism is arranged in the working box and is positioned at the opening side of the working box;

the steel pipe overturning mechanism is configured to be used for taking a steel pipe from the steel pipe conveying mechanism on one side of the working box along the second direction, overturning the steel pipe and inserting the steel pipe into a steel pipe fixing hole of the steel pipe clamp along the third direction;

the steel pipe to be installed along the second direction is sent into the working box through the lower part of the steel pipe and the groove; the steel pipe to be installed in the third direction is conveyed into the working box through the upper part of the steel pipe and the groove;

the fastening mechanism walking driving mechanism is arranged on a bottom plate of the working box and extends along a second direction;

the steel pipe clamp fastening mechanism is arranged on the fastening mechanism walking driving mechanism and can move along a second direction, and the steel pipe clamp fastening mechanism is used for fastening a steel pipe and a steel pipe clamp in the steel pipe clamp assembling groove;

the automatic installation method of the fastener type steel pipe scaffold comprises the following steps:

I.1. the transverse movement mechanism firstly drives the rack to travel to a position where steel pipe construction is to be carried out along a first direction of a working surface, and the transverse movement mechanism stops moving; then, the longitudinal movement mechanism drives the rack to move forwards along the second direction of the working surface and gradually approaches the installed vertical steel pipe, and the longitudinal movement mechanism stops moving after reaching the position of the steel pipe;

the pipe holding mechanism holds the installed vertical steel pipe tightly, so that the position of the frame is fixed after the frame runs in place;

I.2. the lifting mechanism moving mechanism firstly drives the mounting plate lifting mechanism to move backwards along a second direction, so that the mounting plate, the steel pipe conveying mechanism and the scaffold assembling mechanism are separated from the steel pipe backwards by a set distance;

then, the mounting plate lifting mechanism acts and drives the mounting plate, the steel pipe conveying mechanism and the scaffold assembling mechanism to ascend to a working height position, and the mounting plate lifting mechanism stops acting;

the lifting mechanism moving mechanism drives the mounting plate lifting mechanism to move forwards to the initial position of the mounting plate lifting mechanism;

I.3. the moving tank body walking driving mechanism drives the moving tank body to be pushed out forwards;

I.4. the steel pipe clamp hoisting mechanism sequentially takes the first steel pipe clamp and the second steel pipe clamp out of the steel pipe clamp storage groove, puts the first steel pipe clamp into the fixed groove body, and puts the second steel pipe clamp into the movable groove body;

I.5. the moving tank body walking driving mechanism drives the moving tank body to retract backwards to the initial position of the moving tank body along the second direction; at the moment, the first steel pipe clamp and the second steel pipe clamp are combined to form a steel pipe clamp;

I.6. the two steel pipe conveying mechanisms respectively convey steel pipes to the scaffold assembling mechanism, one of the steel pipe conveying mechanisms conveys the steel pipes into the steel pipe from the upper part of the steel pipe feeding groove, and the step I.7 is carried out;

the other steel pipe conveying mechanism conveys the steel pipe into the steel pipe conveying groove from the lower part of the steel pipe and goes to step I.8;

I.7. the steel tube turnover mechanism converts the horizontally placed steel tube into a vertically placed steel tube, inserts the vertical steel tube into the steel tube fixing hole at the top of the steel tube clamp, and then turns to step I.9;

I.8. horizontally inserting the steel pipe into the steel pipe fixing hole at the side part of the steel pipe clamp from one side, and turning to step I.9;

I.9. under the drive of the fastening mechanism walking drive mechanism, the steel pipe clamp fastening mechanism moves forwards to the position of the steel pipe clamp, and the steel pipe clamp fastening mechanism screws the bolt on the steel pipe clamp to realize the installation of the steel pipe;

at this point, the installation of one position point of the scaffold is completed, the scaffold installation robot retreats backwards, and each working mechanism resets;

I.10. repeating the steps I.1-I.9 until all the position points on the current working surface are installed;

I.11. and transferring the scaffold mounting robot to another working surface, and repeating the process until the scaffold is built.

The invention has the following advantages:

compared with the prior art in which the scaffold is manually built, the method greatly saves labor and effectively improves the mounting efficiency of the scaffold.

Drawings

Fig. 1 is a schematic side view of a scaffold mounting robot according to an embodiment of the present invention;

fig. 2 is another schematic structural view of the scaffold mounting robot according to the embodiment of the present invention;

fig. 3 is a front view of a scaffold mounting robot in an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a rack according to an embodiment of the present invention;

FIG. 5 is a schematic side view of the frame with the lateral motion mechanism removed according to an embodiment of the present disclosure;

FIG. 6 is a schematic view of another side of the frame with the lateral motion mechanism removed in accordance with an embodiment of the present invention;

FIG. 7 is a schematic structural diagram of a power driving mechanism of the longitudinal movement mechanism in the embodiment of the invention;

FIG. 8 is a schematic structural diagram of a pipe embracing mechanism according to an embodiment of the present invention;

FIG. 9 is a rear view of a tube embracing mechanism in an embodiment of the present invention;

FIG. 10 is a schematic view of the mounting of the stationary clamp arm in an embodiment of the present invention;

FIG. 11 is a schematic structural view of a movable clamp arm according to an embodiment of the present invention;

FIG. 12 is a schematic structural view of a steel pipe conveying mechanism according to an embodiment of the present invention (one side plate is not shown);

FIG. 13 is a side view of the steel pipe conveying mechanism of FIG. 12;

FIG. 14 is a schematic view of the mounting of the gear transmission mechanism in an embodiment of the present invention;

FIG. 15 is a schematic view of the second stopper retracting into the second stopper mounting groove according to the embodiment of the present invention;

FIG. 16 is a schematic structural view of a steel pipe clamp according to an embodiment of the present invention;

FIG. 17 is a schematic side view of the steel pipe and steel pipe clamp assembly slot, steel pipe clamp fastening mechanism and fastening mechanism travel driving mechanism in combination according to an embodiment of the present invention;

FIG. 18 is a schematic structural view of the other side of the steel pipe and steel pipe clamp assembling groove, the steel pipe clamp fastening mechanism and the fastening mechanism walking driving mechanism combined together according to the embodiment of the present invention;

FIG. 19 is a top view of the steel pipe in combination with the steel pipe clamp mounting groove, the steel pipe clamp fastening mechanism, and the fastening mechanism travel drive mechanism in an embodiment of the present invention;

FIG. 20 is a schematic structural view of a steel pipe clamp lifting clamp in the embodiment of the present invention;

FIG. 21 is a schematic structural view of a steel tube turnover mechanism in an embodiment of the present invention;

FIG. 22 is a schematic view of an installation structure of a steel pipe casing body according to an embodiment of the present invention;

fig. 23 is a diagram showing a state in which the scaffold mounting robot is used in the embodiment of the present invention;

the steel pipe clamping and transporting device comprises a machine frame 1, a pipe clamping mechanism 2, a mounting plate 3, a steel pipe conveying mechanism 4, a transverse moving mechanism 5, a longitudinal moving mechanism 6, a mounting plate lifting mechanism 7, a lifting mechanism moving mechanism 8, a scaffold assembling mechanism 9, a working box 10, a steel pipe clamp storage groove 11, a steel pipe and steel pipe clamp assembling groove 12, a steel pipe clamp hoisting mechanism 13, a steel pipe overturning mechanism 14, a steel pipe clamp fastening mechanism 15, a fastening mechanism walking driving mechanism 16, a steel pipe clamp 17, a steel pipe fixing hole 18, a bolt 19 and a working surface 20; 101-upper plate, 102-lower plate, 103-plate connecting frame, 104, 105-U-shaped notch, 106-supporting fixing plate, 107-telescopic mechanism, 108-groove, 109-strip-shaped hole, 201-fixed clamping arm, 202-movable clamping arm I, 203-movable clamping arm II, 204, 205-guide column group, 206, 207 driving groove, 208-first clamping groove, 209, 210-second clamping groove, 211-circular clamping area, 212, 213-rectangular groove, 214-movable clamping arm opening and closing driving plate, 215, 216-movable clamping arm opening and closing driving plate driving unit, 401-box body, 402-partition plate I, 403-partition plate II, 404-push plate I, 405-push plate II, 406-steel pipe placing opening, 407-steel pipe dropping channel I, 408-a second steel tube falling channel, 409-a groove, 410-a guide block, 411-an inclined plane, 412-a circular through hole, 413a, 413 b-a gear, 414a, 414 b-a gear groove, 415-a first stop, 416-a first stop mounting groove, 417-a second stop, 418-a second stop mounting groove, 419-a first push plate driving mechanism, 420-a second push plate driving mechanism, 421-a roller groove, 422-a roller, 423, 424-a roller groove baffle, 425-a baffle mounting groove, 426-a circular through hole, 501-a transverse moving mechanism power driving mechanism, 502-a first transverse driving traveling wheel, 503-a driving shaft, 504-a first transverse driven traveling wheel, 505-a driven shaft, 601-a first longitudinal driving traveling wheel, 602-a telescopic bracket, 603-a first longitudinal driven travelling wheel, 604-a telescopic bracket, 605-a driving motor, 606-a motor mounting seat, 607-a motor mounting seat fixing plate, 608-a motor mounting groove, 609-a motor mounting seat moving mechanism, 610-an assembling groove, 611-a first transmission shaft, 612-a second transmission shaft, 613-a spring, 614-a clamping groove, 615-a clamping block, 8a, 8b and 8c lead screw driving units, 801-a moving mechanism driving motor, 802-a lead screw mounting seat, 803-a lead screw, 804-a lead screw nut, 805-a connecting block, 1001-a steel pipe upper part feeding groove, 1002-a steel pipe lower part feeding groove, 1003 and 1004-an auxiliary transmission gear, 1401-a turnover mechanism mounting plate, 1402-a telescopic mechanism, 1403-a steel pipe sleeve mounting plate, 1404-a steel pipe sleeve mounting plate rotation driving mechanism, 1405-a steel pipe centering mechanism, 1405 a-an electric telescopic rod, 1405 b-a support groove bracket, 1406-a mounting plate, 1407-a steel pipe sleeve body, 1408-an electric telescopic rod, 1409-an auxiliary steel pipe centering mechanism, 1409 a-an auxiliary centering mechanism moving mechanism, 1409 b-an electric telescopic rod, 1409 c-a support groove bracket, 1501-a fastening mechanism mounting frame, 1501 a-a first mounting plate, 1501 b-a second mounting plate, 1501 c-a connecting frame, 1502-a fastening mechanism driving motor, 1503-a fastening mechanism driving gear, 1504-a fastening mechanism driven gear, 1505-a fastening nut, 17 a-a steel pipe clamp I and 17 b-a steel pipe clamp II.

Detailed Description

The invention is described in further detail below with reference to the following figures and detailed description:

example 1

This embodiment 1 has mentioned a scaffold installation robot to replace artifical installation that realizes steel pipe scaffold.

As shown in fig. 1 to 3, the scaffold installation robot in this embodiment includes a frame 1, a traveling mechanism, a pipe embracing mechanism 2, an installation plate 3, a steel pipe conveying mechanism 4, and a scaffold assembling mechanism 9.

As shown in fig. 4 and 5, the rack 1 includes an upper plate 101 and a lower plate 102; wherein the upper and lower plates 101 and 102 are each stretched in a first direction, which is a left-right direction in fig. 4 and 5.

The upper plate 101 and the lower plate 102 are both square flat plates in this embodiment. The length of the upper plate 101 is greater than that of the lower plate 102, so that the following first longitudinal driving walking wheels and first longitudinal driven walking wheels can be conveniently installed.

The corresponding ends of the upper plate 101 and the lower plate 102 are connected by plate connecting frames 103, respectively. The present embodiment does not limit the structure of the laminate connecting frame 103 as long as the connection between the two can be achieved.

The traveling mechanism comprises a transverse moving mechanism 5 and a longitudinal moving mechanism 6.

The transverse moving mechanism 5 and the longitudinal moving mechanism 6 are both mounted on the rack 1, the transverse moving mechanism 5 is used for driving the rack 1 to move in a first direction, and the longitudinal moving mechanism 6 is used for driving the rack 1 to move in a second direction.

The second direction is the front-rear direction in fig. 4 and 5. Of course, the front, rear, left and right directions are only for convenience of description of the present embodiment, and may be the same as or different from the front, rear, left and right directions of the scaffolding during actual installation.

Therefore, it is only necessary to ensure that the first direction and the second direction are two directions perpendicular to each other in the horizontal plane.

As shown in fig. 4, the lateral movement mechanism 5 includes a set of first lateral driving running wheels and a set of first lateral driven running wheels; the first transverse driving traveling wheel set is located on the left side of the first transverse driven traveling wheel set.

The first lateral active traction wheel set is configured with a lateral movement mechanism power drive mechanism 501.

The first transverse active road wheel set includes two first transverse active road wheels 502, and the two first transverse active road wheels 502 are respectively located at opposite sides of the lower plate along the second direction, that is, at the front side and the rear side of the lower plate 102.

Two first transverse driving road wheels 502 are connected through a driving shaft 503.

The transverse moving mechanism power driving mechanism 501 is mounted on the lower plate 102 and connected with the driving shaft 503, and drives the driving shaft 503 to rotate so as to drive the first transverse driving road wheel 502 to walk.

The power driving mechanism 501 of the lateral movement mechanism adopts an existing worm and gear driving mechanism.

On the lower plate 102, one driving shaft support boss (not shown) is provided at each of front and rear end portions of the driving shaft 503, and the two driving shaft support bosses are provided for supporting the driving shaft 503.

The first laterally driven road wheel group includes two first laterally driven road wheels 504, and the two first laterally driven road wheels 504 are respectively located at opposite sides of the lower deck 102 in the second direction, that is, at front and rear sides of the lower deck 102.

The two first transverse driven road wheels 504 are connected through a driven shaft 505.

One driven shaft support sleeve (not shown) is provided on the lower plate 102 at positions corresponding to the front and rear end portions of the driven shaft 505, respectively, and the two driven shaft support sleeves are used for supporting the driven shaft 505.

As shown in fig. 5 and 6, the longitudinal movement mechanism 6 includes a first longitudinal driving running wheel group and a first longitudinal driven running wheel group. Wherein, the first longitudinal driving running wheel group and the first longitudinal driven running wheel group are respectively provided with two groups.

A group of first longitudinal driving traveling wheel sets and a group of first longitudinal driven traveling wheel sets are respectively arranged at the left end part and the right end part of the frame 1. Taking the first longitudinal driving running wheel set and the first longitudinal driven running wheel set at the left end of the frame 1 as an example:

the first longitudinal active walking wheel set comprises two first longitudinal active walking wheels 601 arranged along a second direction (namely, a front-back direction); each first longitudinal driving road wheel 601 is provided with a longitudinal motion mechanism power driving mechanism.

The first longitudinal active road wheel 601 can be driven to move along the front and back direction by the longitudinal moving mechanism power driving mechanism.

The first longitudinal active running wheel set is mounted on the upper deck 101 by a telescopic bracket 602.

The retractable bracket 602 includes an electric retractable rod and a road wheel mounting bracket.

Wherein, two first vertical initiative walking wheels 601 are all installed on the walking wheel installing support. One end of an electric telescopic rod of the telescopic support 602 is mounted on the upper plate 101, and the other end is connected with the walking wheel mounting support.

The first longitudinal driving walking wheel 601 is driven by the electric telescopic rod to move up and down.

The first longitudinal driven traveling wheel group comprises two first longitudinal driven traveling wheels 603 arranged along a second direction (namely, a front-back direction); the first longitudinally driven running wheel set is mounted on the upper deck 101 by means of a telescopic support 604.

The structure of the retractable stand 604 is the same as the retractable stand 602, and the detailed description is omitted here.

The above longitudinal moving mechanism 6 can be retracted when not in use, avoiding affecting the movement of the transverse moving mechanism 5.

As shown in fig. 7, the longitudinal moving mechanism power driving mechanism includes the following structures:

the driving motor 605, the motor mount 606, the motor mount fixing plate 607, the motor mount groove 608, the motor mount moving mechanism 609, the fitting groove 610, the first transmission shaft 611, and the second transmission shaft 612.

The motor mounting groove 608 is disposed on the lower plate 102 and extends in a first direction (i.e., left-right direction). The motor mount fixing plate 607 is installed on the lower plate 102 and positioned at the right side of the motor installation groove 608.

Motor mount 606 and motor mount moving mechanism 609 are both located within motor mounting slot 608. Wherein, the motor mounting seat moving mechanism 609 is positioned at the left side of the motor mounting groove 608.

The right end of the motor mounting block 606 is connected to a motor mounting block fixing plate 607 via a spring 613.

The motor mounting seat moving mechanism 609 is connected to the motor mounting seat 606 and is configured to drive the motor mounting seat 606 to move in the left-right direction in the motor mounting groove 608, and the driving motor 605 is disposed on the motor mounting seat 606.

The assembly recess 610 is provided on the lower plate 102 with the assembly recess 610 facing upward.

One end of the first transmission shaft 611 is mounted on the first longitudinal active road wheel 601, and the other end of the first transmission shaft 611 extends into the assembly groove 610; one end of the second transmission shaft 612 is connected to an output shaft of the driving motor 605, and the other end thereof extends into the fitting recess 610.

The second transmission shaft 612 is connected to the output shaft of the driving motor 605 through a coupling.

The coupling end of the first transmission shaft 611 and the second transmission shaft 612 is provided with a matching structure, and the first transmission shaft 611 and the second transmission shaft 612 can be coupled and separated in the left-right direction through the matching structure.

The fitting structure here means that the first transmission shaft 611 and the coupling end of the second transmission shaft 612 are fitted, for example, a locking groove 614 is provided at the coupling end of the first transmission shaft 611, and a locking block 615 is provided at the coupling end of the second transmission shaft 612.

When the clamping groove 614 is combined with the clamping block 615, the first transmission shaft 611 and the second transmission shaft 612 are connected into a whole, so that power transmission is realized; of course, the first transmission shaft 611 and the second transmission shaft 612 can be quickly separated in the left-right direction.

When the frame 1 moves in the left-right direction, in order to avoid the influence of the first longitudinal driving road wheel 601 and the first longitudinal driven road wheel 603, the first transmission shaft 611 and the second transmission shaft 612 need to be separated.

The separation process is as follows: the motor mounting seat moving mechanism 609 pushes the motor mounting seat 606 to move to the right, the spring 613 stores energy, and the first transmission shaft 611 is separated from the second transmission shaft 612 because the driving motor 605 is arranged on the motor mounting seat 606.

After the first transmission shaft 611 is separated from the second transmission shaft 612, the first longitudinal driving traveling wheel 601 and the first longitudinal driven traveling wheel 603 are lifted up under the driving of the retractable brackets 602 and 604, and the transverse movement of the rack 1 is not affected.

When the frame 1 needs to move back and forth, the first longitudinal driving road wheel 601 and the first longitudinal driven road wheel 603 first fall to contact with the working surface 20 under the driving of the telescopic brackets 602 and 604.

Then the first transmission shaft 611 is combined with the second transmission shaft 612 (contrary to the above-mentioned separation process), and finally the first longitudinal active road wheel 601 is rotated by the driving motor 605, thereby driving the frame 1 to move back and forth.

The pipe embracing mechanism 2 is arranged on the rack 1 and used for realizing the position fixation of the rack 1 after running in place.

As shown in fig. 8 and 9, the pipe embracing mechanism 2 includes a fixed clamp arm 201, a movable clamp arm one 202, a movable clamp arm two 203, a movable clamp arm opening and closing drive plate 214, and a movable clamp arm opening and closing drive plate drive mechanism.

The fixed clamping arm 201 is connected between the upper plate 101 and the lower plate 102, and is located at a middle position, such as a front middle position, of a corresponding end of the upper plate 101 and the lower plate 102, as shown in fig. 10.

The first movable clamping arm 202 and the second movable clamping arm 203 are symmetrically arranged.

As shown in fig. 9, a set of guide posts, such as a guide post set 204 and a guide post set 205, are obliquely arranged in a line shape on the back surface of each of the first movable clamp arm 202 and the second movable clamp arm 203.

The number of the guide columns in each guide column group is at least three, and all the guide columns are arranged in a shape like a Chinese character 'yi'.

The guide post sets on the first movable clamping arm 202 and the second movable clamping arm 203 are symmetrically arranged.

Two driving grooves, such as the driving groove 206 and the driving groove 207, are formed in the movable clamp arm opening and closing driving plate 214.

The driving groove 206 and the driving groove 207 are linear grooves.

The inclination direction of the driving groove 206 is consistent with the inclination direction of the guide column group 204 of the first movable clamping arm 202, and the inclination direction of the driving groove 207 is consistent with the inclination direction of the guide column group 205 on the second movable clamping arm 203.

The guide column group 204 and the guide column group 205 are respectively positioned in the driving groove 206 and the driving groove 207.

The driving mechanism of the movable clamping arm opening and closing driving plate is located between the upper plate 101 and the lower plate 102, connected with the movable clamping arm opening and closing driving plate 214, and used for driving the movable clamping arm opening and closing driving plate 214 to move along a third direction.

Because the movable clamping arm opening and closing driving plate 214 is connected with the first movable clamping arm 202 and the second movable clamping arm 203 at the same time, the two movable clamping arms can be driven to move close to or separate from the middle (namely the fixed clamping arm 201) at the same time.

As shown in fig. 10, in the present embodiment, the fixed clamp arm 201 is provided with a first clamp groove 208, and the extending direction of the first clamp groove 208 is along a third direction, i.e. along the length direction of the fixed clamp arm 201.

As shown in fig. 11, the first movable clamping arm 202 and the second movable clamping arm 203 are symmetrical in structure.

A second clamping groove, such as second clamping grooves 209 and 210, is respectively arranged on the first movable clamping arm 202 and the second movable clamping arm 203, and the extending direction of the second clamping grooves 209 and 210 is consistent with the extending direction of the first clamping groove.

The first clamping groove 208 is in a semi-circular arc shape, and the second clamping grooves 209 and 210 are in 1/4 circular arc shapes; when the fixed clamp arm 201, the first movable clamp arm 202 and the second movable clamp arm 203 are combined, a circular clamp area 211 is formed among the three.

Circular centre gripping region 211 can realize holding tightly the steel pipe to realize the rigidity of robot operation after targetting in place.

In addition, as shown in fig. 11, a rectangular groove 212 (the extending direction is the same as the second holding groove 209) is further provided at the side of the second holding groove 209; similarly, a rectangular groove 213 is formed at the side of the second holding groove 210.

When the fixed clamp arm 201, the first movable clamp arm 202 and the second movable clamp arm 203 are combined together, a combined area is formed by the rectangular groove 212 and the rectangular groove 213, and the fixed clamp arm 201 is located in the combined area.

U-shaped notches 104 and 105 are also provided in the middle of the upper deck 101 and the lower deck 102, respectively, as shown in FIG. 5. Through the U-shaped breach, can avoid the top of frame 1 and bottom limit portion influence the assembly of scaffold frame.

As shown in fig. 5, a supporting and fixing plate 106 and a telescoping mechanism 107 are further provided below the lower plate 102. Wherein, the bottom of the lower plate 102 is connected with the supporting and fixing plate 106 through a telescopic mechanism 107.

Wherein, supporting and fixing plate 106 is square board, and the limit portion that corresponds to set up U-shaped breach 105 at supporting and fixing plate 106 is equipped with recess 108, avoids influencing the assembly of scaffold frame installation robot to scaffold frame.

The telescopic mechanism 107 is an electric telescopic rod, and is used for pushing the supporting and fixing plate 106 downwards to the working surface 20 after the robot runs in place and the steel pipe is tightly held by the holding mechanism, so that the robot is effectively prevented from moving.

The driving mechanism of the movable clamping arm opening and closing driving plate adopts two groups of driving units 215 and 216 of the movable clamping arm opening and closing driving plate. Wherein, the driving units 215 and 216 of the opening and closing driving plate of the movable clamping arm are screw driving units.

A pair of side portions of the movable clamping arm opening and closing drive plate 214 are respectively connected to the screw nuts of the movable clamping arm opening and closing drive plate drive units 215 and 216, and the movable clamping arm opening and closing drive plate 214 is driven to move up and down through the screw drive unit.

As shown in fig. 1 to 3, the mounting plate 3 is located above the rack 1, and extends in a first direction with the rack 1.

An installation plate lifting mechanism 7 is arranged between the frame 1 and the installation plate 3. The mounting plate lifting mechanisms 7 are at least two, and the mounting plate 3 is lifted and lowered together through the mounting plate lifting mechanisms 7.

In the embodiment, the mounting plate lifting mechanisms 7 are preferably all scissor type lifting mechanisms.

The bottom of each mounting plate lifting mechanism 7 is provided with a lifting mechanism moving mechanism 8, and the lifting mechanism moving mechanism 8 is installed on the rack 1 (upper plate 101) and used for driving the mounting plate lifting mechanisms 7 to move along the second direction.

Taking one of the lifting mechanism moving mechanisms 8 as an example:

each of the elevating mechanism moving mechanisms 8 includes at least two lead screw driving units, such as lead screw driving units 8a, 8b, 8c shown in fig. 6, arranged in parallel in the second direction. Taking one of the screw drive units 8a as an example:

as shown in fig. 6, the lead screw drive unit 8a includes a movement mechanism drive motor 801, a lead screw mount 802, a lead screw 803, and a lead screw nut 804, and an output shaft of the movement mechanism drive motor 801 is connected to the lead screw 803 through a coupling.

The lead screw 803 extends in a second direction, and an end of the lead screw 803 is mounted on the lead screw mount 802.

The lead screw nut 804 is mounted on the lead screw 803.

A strip-shaped hole 109 extending along the same direction as the lead screw is arranged on the upper plate 101 corresponding to each lead screw 803. And a connecting block 805 is arranged between the lead screw nut 804 and the corresponding position at the bottom of the mounting plate lifting mechanism 7.

The bottom of the mounting plate lifting mechanism 7 passes through the strip-shaped hole 109 through a connecting block 805 and is connected with a screw nut 804.

The mounting plate lifting mechanism 7 can realize the movement in the second direction under the drive of the lifting mechanism moving mechanism 8.

The design can effectively avoid the influence of the installed transverse steel pipe on the installation plate lifting mechanism 7 in the lifting process of driving the installation plate 3, the scaffold assembling mechanism 9, the steel pipe conveying mechanism 4 and the like. In particular, the amount of the solvent to be used,

when the mounting plate 3, the scaffold assembling mechanism 9 and the steel pipe conveying mechanism 4 need to be lifted, the lifting mechanism moving mechanism 8 firstly drives them to move backwards, and when the mounting plate is lifted to the working position, the lifting mechanism moving mechanism drives them to move forwards to the steel pipe mounting position.

As shown in fig. 1 to 3, the scaffold assembly mechanism 9 and the steel pipe conveying mechanism 4 are both provided on the mounting plate 3; the number of the steel pipe conveying mechanisms 4 is two, and the two steel pipe conveying mechanisms are respectively positioned at the left side part and the right side part of the scaffold assembling mechanism 9.

Each steel pipe conveying mechanism 4 is used for conveying steel pipes required for building the scaffold to the scaffold assembling mechanism 9.

Taking one of the steel pipe conveying mechanisms 4 as an example:

the steel pipe conveying mechanism 4 comprises a square box body 401, a first partition plate 402, a second partition plate 403, a first push plate 404, a second push plate 405, a roller conveying mechanism, a gear conveying mechanism and other components which are positioned in the box body 401.

A steel pipe inlet 406 is arranged on the top plate 401a of the box body and used for placing the material steel pipe into the box body 401.

Partition one 402 is mounted on a first side plate 401b of the cabinet 401, as shown in fig. 13, for example. And a first steel pipe falling channel 407 is arranged between the first partition 402 and the second side plate 401c of the box body 401, so that the steel pipes can fall conveniently.

The second partition 403 is attached to the second side plate 401c of the case 401, as shown in fig. 13, for example. And a second steel pipe falling channel 408 is arranged between the second partition plate 403 and the first side plate 401b of the box body, so that the steel pipe can fall conveniently.

As can be seen from fig. 12 and 13, the first side plate 401b and the second side plate 401c are opposite side plates.

The first partition plate 402 and the second partition plate 403 are both horizontally arranged, and the first partition plate 402 is positioned above the second partition plate 403.

The first push plate 404 is located above the first partition 402, and the first push plate 404 is used for pushing the steel tube above the first partition 402 to fall onto the second partition 403 through the first steel tube falling channel 407.

Wherein, the pushing direction of the first pushing plate 404 is horizontally towards the first steel pipe falling channel.

The first push plate 404 is provided with a first push plate driving mechanism 419, the first push plate driving mechanism 419 is connected to the first side plate 401b, and the first push plate 404 pushes the steel pipe under the pushing of the first push plate driving mechanism 419.

In this embodiment, the first push plate driving mechanism 419 is an electric telescopic rod.

The second push plate 405 is located above the second partition plate 403, and the second push plate 405 is used for pushing the steel pipe above the second partition plate 403 to fall onto the bottom plate 401d of the box 401 through the second steel pipe falling channel 408.

Wherein, the pushing direction of the second pushing plate 405 horizontally faces the second steel pipe falling channel 408.

The second push plate 405 is provided with a second push plate driving mechanism 420, and the second push plate driving mechanism 420 is connected to the second side plate 401 c; under the pushing of the second push plate driving mechanism 420, the second push plate 405 pushes the steel pipe.

In this embodiment, the second push plate driving mechanism 420 is an electric telescopic rod.

A semicircular arc-shaped groove 409 is formed in the bottom plate 401d, and the extending direction of the groove 409 is parallel to the extending direction of the first push plate 404. The steel pipe falling through the second steel pipe falling passage 408 enters the groove 409.

In order to facilitate the smooth entering of the steel pipe into the groove 409, the following design is also performed in the embodiment:

a guide block 410 is arranged on the box body bottom plate 401d, and the guide block 410 is positioned right below the second steel pipe falling channel 408; an inclined plane 411 is provided on the guide block 410 to guide toward the groove.

The guide block 410 in this embodiment is preferably a triangular block in which the inclined side of the triangular block is used as the inclined plane 411.

Through the guide block 410, the steel pipe can smoothly enter the groove 409. Circular through holes, such as circular through hole 412, are provided on the other opposite side plate of the case 401 (e.g., side plate not shown in fig. 12 and side plate 401e) at corresponding grooves 409.

As can be seen, the set of opposing side panels is the side panel adjacent to the first side panel 401b and the second side panel 401 c.

As can be seen from fig. 13, the groove 409 is aligned with the lower semi-circular arc of the circular through hole 412 to ensure smooth delivery of the steel pipe. The gear transmission mechanism is positioned at the groove 409 and used for conveying the steel pipe in the groove 409, so that the steel pipe is conveyed from the bottom.

As shown in fig. 14, the gear transmission mechanism includes two gears, gears 413a, 413b, respectively.

Wherein the gears 413a, 413b are located on opposite sides of the groove 409, respectively.

A gear groove 414a, 414b is provided on the bottom plate 401d corresponding to the mounting position of each gear, wherein the gear grooves 414a, 414b are respectively communicated with the groove 409, and the gears 413a, 413b are respectively located in the corresponding gear grooves.

Above design can guarantee that the steel pipe can be stirred and carry along recess 409 after gear 413a, 413b installation.

A gear drive mechanism (not shown) is disposed below each gear. The gear driving mechanism in this embodiment is, for example, a driving motor, wherein an output shaft of the driving motor is connected to the gear.

Under the action of the two driving motors, the gears 413a and 413b rotate and realize the conveying of the steel pipe along the groove 409.

In addition, a first stop 415 is provided at the free end of the second partition 403.

A first stop block mounting groove 416 is formed in the surface of the second partition plate 403 at a position corresponding to the first stop block 415, and the first stop block 415 is positioned in the first stop block mounting groove 416; a first block driving mechanism (not shown) is further arranged in the first block mounting groove 416.

The first stop block driving mechanism adopts an electric telescopic rod and is connected with the bottom of the first stop block 415.

In this embodiment, the number of the electric telescopic rods connected to the bottom of each first stopper 415 is, for example, but not limited to, two.

When the steel pipe does not need to be conveyed from the bottom of the steel pipe conveying mechanism 4, the first stop block 415 extends out of the first stop block mounting groove 416, and the steel pipe cannot enter the space above the bottom plate 401 d.

When the steel pipe needs to be conveyed from the bottom of the steel pipe conveying mechanism 4, the first stop block 415 retracts into the first stop block mounting groove 416, and at the moment, the top of the first stop block 415 is flush with the surface of the second partition plate 403, so that the pushing of the steel pipe cannot be influenced.

Similarly, a second stop 417 is disposed on the inclined plane 411.

A second stop block mounting groove 418 is formed in the guide block 410 at a position corresponding to the second stop block 417, and the second stop block 417 is located in the second stop block mounting groove 418; a second block driving mechanism (not shown) is further disposed in the second block mounting groove 418.

The second block driving mechanism adopts an electric telescopic rod and is connected with the bottom of the second block 417.

In this embodiment, the number of the electric telescopic rods connected to the bottom of each second stop 417 is, for example, but not limited to, two.

When the steel pipe does not need to be conveyed from the bottom of the steel pipe conveying mechanism 4, the second stopper 417 extends out of the second stopper mounting groove 418, and the steel pipe does not enter the space above the bottom plate 401 d.

When the steel pipe needs to be conveyed from the bottom of the steel pipe conveying mechanism 4, the second stop block 417 retracts into the second stop block mounting groove 418, and at the moment, the top of the second stop block 417 is level with the inclined plane 411, so that the pushing of the steel pipe cannot be influenced.

In this embodiment, the steel pipe transport mechanism 4 can transport a steel pipe from above in addition to transporting the steel pipe from the bottom, and in this case, a roller transport mechanism is required. The structure of the roller conveying mechanism is shown in fig. 12.

The roller conveying mechanism is arranged above the first partition plate 402; the roller transmission mechanism comprises a roller groove 421 arranged along the first direction and a plurality of rollers 422 arranged in the roller groove; and part of the rollers are power rollers, and part of the rollers are unpowered rollers.

The arrangement direction of the rollers 422 is perpendicular to the first direction, i.e., the conveying direction of the steel pipes. A roller groove baffle 423, 424 is respectively installed on the opposite side of the roller groove 421, and the extending direction of the roller groove baffle is the same as that of the roller groove.

A baffle installation groove, such as baffle installation groove 425, is provided on the first partition plate 402 at a position corresponding to each roller groove baffle 423, 424. Wherein the roller slot baffles 423, 424 are located in the respective baffle mounting slots.

Further, a telescopic mechanism (not shown) connected to the bottom of the corresponding roller slot fence is provided in each fence installation groove. The telescopic mechanism adopts an electric telescopic rod, and two electric telescopic rods are arranged in each baffle plate mounting groove.

Through the telescopic mechanism, the roller groove baffle plates 423 and 424 can be driven to extend out of or retract into the baffle plate installation grooves.

Circular through holes, such as circular through holes 426, are provided on the other opposite side plate of the casing 401, which is adjacent to the first side plate and the second side plate, at positions corresponding to the roller grooves 421, respectively.

When the steel pipe needs to be conveyed from the upper part, the roller groove baffle 424 extends out to prevent the steel pipe from falling from the steel pipe falling passage, and when the steel pipe reaches the roller groove 421, the steel pipe is pushed by the roller 422 to be sent out from the circular through hole 426.

The scaffold assembling mechanism 9 comprises a working box 10, a steel pipe clamp storage groove 11, a steel pipe and steel pipe clamp assembling groove 12, a steel pipe clamp hoisting mechanism 13, a steel pipe overturning mechanism 14, a steel pipe clamp fastening mechanism 15 and a fastening mechanism walking driving mechanism 16.

The work box 10 is a square box with one side open, and the opening of the work box 10 faces the front side.

The left and right side plates of the working box 10 are provided with a steel pipe upper part feeding groove 1001 and a steel pipe lower part feeding groove 1002; wherein, the steel pipe upper part feeding groove 1001 and the steel pipe lower part feeding groove 1002 are both positioned at the opening of the work box.

The upper steel pipe feeding grooves 1001 on the left and right side plates of the work box 10 are provided corresponding to each other in the first direction, and the lower steel pipe feeding grooves 1002 on the left and right side plates of the work box 10 are also provided corresponding to each other in the first direction.

In this embodiment, the steel pipe upper feeding groove 1001 and the steel pipe lower feeding groove 1002 are both U-shaped grooves, wherein the opening of the steel pipe upper feeding groove 1001 faces upward, and the opening of the steel pipe lower feeding groove 1002 faces forward.

In order to ensure that the steel pipe conveying mechanism 4 smoothly conveys steel pipes into the working box, the following design is also carried out:

a set of upper tube gear auxiliary gears is installed at the tube upper feed groove 1001 of the work box 10, and is aligned with the roller groove 421 and the tube upper feed groove 1001 in the first direction.

The upper steel pipe gear auxiliary transmission mechanism comprises a pair of auxiliary transmission gears 1003 which are horizontally installed, a driving motor is arranged at the bottom of each auxiliary transmission gear 1003, and the driving motor drives the auxiliary transmission gears 1003 to convey steel pipes.

Similarly, a group of lower steel pipe gear auxiliary transmission mechanisms are arranged at the upper steel pipe feeding groove of the working box, and are aligned with the groove 409 and the lower steel pipe feeding groove 1002 in the first direction.

Lower steel pipe gear auxiliary transmission mechanism includes a pair of vertical installation and the supplementary transmission gear 1004 towards the place ahead, all is equipped with driving motor in the bottom of every supplementary transmission gear, and the motor drives supplementary transmission gear 1004 and realizes that the steel pipe carries.

The steel pipe clamp storage tank 11 is installed in the work box 10, and is used for storing the steel pipe clamps 17. The structure of the steel pipe clamp is shown in fig. 16. The steel pipe clamp 17 includes a first steel pipe clamp 17a and a second steel pipe clamp 17 b.

When the first steel pipe clamp 17a and the second steel pipe clamp 17b are combined to form the steel pipe clamp 17, steel pipe fixing holes 18, for example, steel pipe fixing holes 18, for receiving steel pipes are formed on a plurality of surfaces of the steel pipe clamp 17, respectively.

The four steel pipes, namely, the upper steel pipe, the lower steel pipe, the left steel pipe and the right steel pipe, are simultaneously placed into the steel pipe fixing holes 18 in the corresponding directions of the steel pipe clamps 17, and then bolts 19 between the first steel pipe clamp 17a and the second steel pipe clamp 17b are screwed down, so that the steel pipes can be fixed.

The first steel pipe clamp 17a and the second steel pipe clamp 17b are placed in pairs and in a split mode in the steel pipe clamp storage groove 11.

In the embodiment, the steel pipe clamps 17a and the second steel pipe clamps 17b are placed in pairs and in a split manner, namely, the steel pipe clamps 17a and the second steel pipe clamps 17b are placed in pairs in the steel pipe clamp storage tank 11, and then are not combined and can be taken out independently.

The steel pipe and steel pipe jig assembling groove 12 is located at the middle position of the opening side of the work box 10, and is provided on the bottom plate of the work box 10, and the steel pipe and steel pipe jig can be mounted in the steel pipe and steel pipe jig assembling groove 12.

As shown in fig. 17, the steel pipe and steel pipe clamp fitting groove 12 includes a fixed groove body 1201 and a moving groove body 1202. The movable trough 1202 is configured with a movable trough traveling driving mechanism for driving the movable trough to move along the second direction.

Two sets of moving trough body walking driving mechanisms are arranged and are respectively positioned at one side of the moving trough body 1202.

The moving trough body walking driving mechanism adopts a gear and rack driving mechanism, namely a horizontal gear 1203 is arranged on the bottom plate of the working box 10, and the bottom of the gear 1203 is driven by a driving motor.

A spur rack 1204 is arranged at the side part of the moving groove body 1202, and the spur rack 1204 and a gear 1203 are arranged.

The design is convenient for smoothly placing the first steel pipe clamp 17a and the second steel pipe clamp 17b into the steel pipe and steel pipe clamp assembling groove 12.

As shown in FIG. 2, the steel pipe clamp hoisting mechanism 13 comprises a steel pipe clamp hoisting clamp 1301 and a three-axis motion driving mechanism 1302. Wherein, the steel pipe clamp hoisting clamp is arranged on the three-axis motion driving mechanism.

The three-axis motion driving mechanism is installed on the inner side wall of the work box 10.

The three-axis motion driving mechanism 1302 is used for driving the steel pipe clamp hoisting clamp to move along the first direction, the second direction and the third direction. In this embodiment, the three-axis motion driving mechanism is a common three-axis motion mechanism, which is not described herein again.

The steel pipe clamp hoisting clamp 1301 sequentially takes out the first steel pipe clamp 17a and the second steel pipe clamp 17b from the steel pipe clamp storage tank 11, puts the taken-out first steel pipe clamp 17a into the fixed tank 1201, and puts the second steel pipe clamp 17b into the movable tank 1202.

The first steel pipe clamp 17a and the second steel pipe clamp 17b are taken out separately and placed in the steel pipe and steel pipe clamp assembling groove 12, so that the influence of the assembled (horizontal or vertical) steel pipe on the placement of the steel pipe clamps is avoided.

As shown in fig. 20, the steel pipe clamp lifting jig 1301 is used for sucking the first steel pipe clamp 17a and the second steel pipe clamp 17b, and includes a clamp mounting plate 1301a, a steel pipe clamp sucking tool 1301b, and a second steel pipe clamp sucking tool 1301 c.

The steel pipe clamp sucking tool 1301b and the second steel pipe clamp 1301c are mounted on the clamp mounting plate 1301a, and the steel pipe clamp sucking tool and the second steel pipe clamp sucking tool are symmetrical in structure.

The steel pipe clamp suction tool 1301b and the steel pipe clamp secondary suction tool 1301c both adopt electromagnets.

Taking one of the electromagnets as an example, each electromagnet is composed of a strip-shaped electromagnet segment L1, a semicircular strip-shaped electromagnet segment L2 and another strip-shaped electromagnet segment L3 which are connected in sequence.

This kind of structure is convenient for laminate well with corresponding steel pipe anchor clamps, guarantees to absorb the effect.

Ceramic plates 1301d are arranged between the steel pipe clamp suction tool 1301b and the steel pipe clamp secondary suction tool 1301c and are separated by the ceramic plates 1301d, and the ceramic plates 1301d are also arranged on the clamp mounting plate 1301 a.

The steel pipe turnover mechanism 14 is installed in the work box 10 and is located at an opening side of the work box 10.

The steel pipe overturning mechanism 14 is used for taking a steel pipe from the steel pipe conveying mechanism 4 on one side of the working box 10 in the second direction, overturning the steel pipe, and inserting the steel pipe into the steel pipe fixing hole 18 of the steel pipe clamp 17 in the third direction.

The steel pipe installed in the second direction (i.e., the left-right direction in fig. 1) is fed into the working box through the steel pipe lower feeding groove 1002; the steel pipe installed in the third direction is fed into the work box 10 through the steel pipe upper feed groove 1001.

As shown in fig. 21, the steel tube turnover mechanism 14 in the present embodiment includes the following structures:

turnover mechanism mounting plate 1401, telescoping mechanism 1402, steel pipe sleeve mounting plate 1403, steel pipe sleeve mounting plate rotation driving mechanism 1404, steel pipe straightening mechanism 1405 and auxiliary steel pipe straightening mechanism 1409.

The telescoping mechanism 1402 is fixedly mounted. Specifically, there are two steel pipe clamp storage tanks 11, and a mounting plate 1406 is provided between the two steel pipe clamp storage tanks 11, and the rear end of the telescopic mechanism 1402 is mounted on the mounting plate 1406.

The telescoping mechanism 1402 is an electric telescopic rod, and the turnover mechanism mounting plate 1401 is of a door-shaped structure. The telescoping mechanism 1402 is connected to the turnover mechanism mounting plate 1401 for driving the turnover mechanism mounting plate 1401 to move in the front-back direction.

The telescoping mechanism 1402 is located at the rear side of the turnover mechanism mounting plate 1401, and the steel pipe sleeve mounting plate rotation driving mechanism 1404 is mounted on the turnover mechanism mounting plate 1401 and located at the front side of the turnover mechanism mounting plate 1401.

The steel pipe sleeve mounting plate rotation drive mechanism 1404 is preferably a rotary motor. The steel pipe sleeve mounting plate rotation driving mechanism 1404 is connected to the steel pipe sleeve mounting plate 1403 and is used for driving the steel pipe sleeve mounting plate 1403 to rotate.

As shown in fig. 22, in the embodiment, the steel pipe sleeve adopts a split structure, which is convenient for taking down the steel pipe sleeve after the vertical steel pipe is installed. The steel pipe sleeve comprises two steel pipe sleeve bodies 1407 with semicircular structures.

Wherein, the middle part of each steel pipe box body 1407 is connected with steel pipe mounting plate 1403 in an articulated way respectively.

An electric telescopic rod 1408 is further arranged between each steel pipe sleeve body 1407 and the steel pipe sleeve mounting plate 1403, one end of the electric telescopic rod 1408 is hinged on the steel pipe sleeve mounting plate, and the other end of the electric telescopic rod 1408 is hinged on the corresponding steel pipe sleeve body.

The electric telescopic rod 1408 drives the corresponding steel pipe sleeve body 1407, so that the steel pipe sleeve can be closed and opened.

The steel pipe straightening mechanism 1405 is arranged on the turnover mechanism mounting plate 1401 and is located on the same side as the steel pipe sleeve.

The steel pipe righting mechanism 1405 comprises an electric telescopic rod 1405a and a supporting groove bracket 1405 b; wherein, the electric telescopic rod 1405a of steel pipe righting mechanism vertically extends, and the support groove support 1405b is hinged at the end of the electric telescopic rod 1405 a.

As shown in fig. 21, the support portion of the support groove bracket 1405b is formed in a semicircular arc shape to facilitate the attachment with the steel pipe.

Two auxiliary steel pipe centralizing mechanisms 1409 are arranged on the top plate of the working box 10; two auxiliary steel tube straightening mechanisms 1409 are respectively located at the opposite ends (i.e., the left end and the right end in fig. 1) of the working box top plate along the first direction.

Each auxiliary steel tube centering mechanism 1409 comprises an auxiliary centering mechanism moving mechanism 1409a, an electric telescopic rod 1409b and a supporting groove bracket 1409 c; wherein the auxiliary righting mechanism moving mechanism 1409a is arranged in the left-right direction.

The auxiliary centering mechanism moving mechanism 1409a is, for example, a slide rail type linear driving mechanism, and each auxiliary centering mechanism moving mechanism 1409a is composed of two slide rail type linear driving units arranged in parallel.

An electric telescopic rod 1409b of the auxiliary steel tube righting mechanism is arranged on a moving mechanism 1409a of the auxiliary righting mechanism, and a supporting groove bracket 1409c of the auxiliary steel tube righting mechanism is hinged on the electric telescopic rod 1409b of the auxiliary steel tube righting mechanism.

The structure of the supporting groove bracket 1409c in this embodiment is the same as that of the supporting groove bracket 1405b, and the description thereof is omitted.

The concrete principle of the operation of the steel tube overturning mechanism 14 in the embodiment is as follows:

in the initial state, the steel pipe sleeve is in a closed state and is horizontally placed. The steel pipe delivered from the upper part of the steel pipe conveying mechanism 4 on one side is delivered into the working box 10 through the steel pipe upper part delivery groove 1001 and inserted into the steel pipe sleeve;

under the drive of the steel pipe sleeve mounting plate rotation driving mechanism 1404, the steel pipe sleeve mounting plate 1403 and the steel pipe sleeve rotate synchronously, and in the rotation process, the steel pipe straightening mechanism 1405 extends upwards to realize the straightening of the steel pipe;

when the steel pipe is in a vertical state, a certain offset still occurs, at the moment, the two auxiliary steel pipe straightening mechanisms 1409 are synchronously drawn close to the middle, and the corresponding supporting groove brackets 1409c are erected on the upper part of the steel pipe to ensure that the steel pipe is in a vertical state.

The telescopic mechanism 1402 is used for driving the turnover mechanism mounting plate 1401 and other components to move backwards integrally, so that the first steel pipe clamp 17a and the second steel pipe clamp 17b can be smoothly placed into the steel pipe and steel pipe clamp assembling groove 12.

As shown in fig. 17 and 18, the fastening mechanism travel drive mechanism 16 is mounted on the bottom plate of the work box 10. The steel pipe clamp fastening mechanism 15 is provided on the fastening mechanism travel drive mechanism 16 and is movable in the second direction.

The steel pipe clamp fastening mechanism 15 is used for fastening the steel pipe and the steel pipe clamp in the steel pipe clamp assembling groove 12.

As shown in fig. 17 to 19, the steel pipe clamp fastening mechanism 15 includes a fastening mechanism mounting bracket 1501, a fastening mechanism driving motor 1502, a fastening mechanism driving gear 1503, a fastening mechanism driven gear, and a fastening nut assembly.

The fastening mechanism mount 1501 includes a first mount plate 1501a and a second mount plate 1501b arranged in parallel in the front-rear direction, and the first mount plate 1501a and the second mount plate 1501b are square plates.

The first mounting plate 1501a is located at the rear side of the second mounting plate 1501b, and the first mounting plate 1501a and the second mounting plate 1501b are connected by a connecting bracket 1501 c.

The fastening mechanism drive motor 1502 is mounted to the first mounting plate 1501a and is coupled to the fastening mechanism drive gear 1503.

There are four driven gears and fastening nut assemblies, and each driven gear and fastening nut assembly is mounted at a corner position of the second mounting plate 1501 b.

Each fastening mechanism driven gear and fastening nut assembly includes a fastening mechanism driven gear 1504, a connecting shaft (not shown), and a fastening nut 1505, which are connected in series.

A connecting shaft hole is formed in the second mounting plate 1501b at a position corresponding to the connecting shaft, and the connecting shaft penetrates through the connecting shaft hole.

When the tightening mechanism driven gear 1504 rotates, the corresponding tightening nut 1505 will rotate with it.

Each fastening mechanism driven gear 1504 and the fastening mechanism driving gear 1503 are located on the rear side of the second mounting plate 1501b, and the fastening mechanism driving gear 1503 simultaneously meshes with each fastening mechanism driven gear 1504.

After installation, the tightening nut 1505 and the tightening mechanism driven gear 1504 are on different sides of the second mounting plate, respectively.

When the fastening mechanism driving motor 1502 rotates, the fastening mechanism driving gear 1503 drives each fastening mechanism driven gear 1504 to rotate synchronously, so that each fastening nut 1505 rotates.

Since the fastening nuts 1505 are connected to the bolts 19 of the steel pipe clamp, the steel pipe clamp 17 can be tightened when the fastening nuts 1505 are rotated, and the steel pipes can be mounted up, down, left, and right.

Example 2

This example 2 describes an automatic installing method of a steel pipe scaffold of a fastener type, which is based on the scaffold installing robot described in the above example 1, instead of manual work, thereby improving the efficiency of scaffold installation.

As shown in fig. 23, the method for automatically installing the clip type steel pipe scaffold comprises the following steps:

I.1. firstly, the transverse moving mechanism 5 drives the frame 1 to travel to a position where steel pipe building is to be performed along a first direction (i.e. left and right directions in fig. 1) of the working surface 20, and the transverse moving mechanism 5 stops moving.

And then, the longitudinal movement mechanism 6 drives the rack 1 to move forwards along the working surface and gradually approaches the installed vertical steel pipe, and the longitudinal movement mechanism 6 stops moving after reaching the position of the steel pipe.

The pipe embracing mechanism 2 embraces the installed vertical steel pipe tightly, and the position of the rack 1 is fixed after the rack runs in place.

I.2. The lifting mechanism moving mechanism 8 firstly drives the mounting plate lifting mechanism 7 to move backwards, so that the mounting plate 3, the steel pipe conveying mechanism 4 and the scaffold assembling mechanism 9 are separated from the steel pipe backwards by a set distance.

This step can avoid the already installed transverse steel pipe from affecting the lifting of the mounting plate 3 and other parts.

Next, the mounting plate lifting mechanism 7 acts to drive the mounting plate 3, the steel pipe conveying mechanism 4 and the scaffold assembling mechanism 9 to ascend to the working height position, and the mounting plate lifting mechanism 7 stops acting.

The lifting mechanism moving mechanism 8 drives the mounting plate lifting mechanism 7 to move forwards to the initial position of the mounting plate lifting mechanism 7.

I.3. The moving tank body travel driving mechanism drives the moving tank body 1202 to push out forwards.

I.4. The steel pipe clamp hoisting mechanism sequentially takes out the first steel pipe clamp 17a and the second steel pipe clamp 17b from the steel pipe clamp storage groove, puts the first steel pipe clamp 17a into the fixed groove body 1201, and puts the second steel pipe clamp 17b into the movable groove body 1202.

The concrete process of taking the first steel pipe clamp 17a and the second steel pipe clamp 17b by the steel pipe clamp hoisting mechanism 13 is as follows:

the three-axis motion driving mechanism 1302 drives the steel pipe clamp lifting clamp 1301 to reach the steel pipe clamp storage tank 11, and then the steel pipe clamp lifting clamp falls to the placement position of a group of steel pipe clamps in the steel pipe clamp storage tank 11.

At the moment, the steel pipe clamp suction tool is attached to the first steel pipe clamp, and the second steel pipe clamp suction tool is attached to the second steel pipe clamp.

The steel pipe clamp sucking tool 1301b is firstly electrified and sucks the first steel pipe clamp 17a, and the first steel pipe clamp 17a is conveyed into the fixing groove body 1201 by the steel pipe clamp hoisting clamp under the driving of the three-axis motion driving mechanism.

Driven by the three-axis motion driving mechanism 1302, the steel pipe clamp hoisting clamp 1301 moves into the steel pipe clamp storage groove 11 again, and falls to the placement position of the group of steel pipe clamps in the steel pipe clamp storage groove.

The second steel pipe clamp suction tool is attached to the second steel pipe clamp; and the second steel pipe clamp suction tool is electrified and sucks the second steel pipe clamp, and the second steel pipe clamp is conveyed into the movable groove body 1202 by the steel pipe clamp hoisting clamp under the driving of the three-axis motion driving mechanism.

Before the steel pipe clamp hoisting mechanism 1301 takes the first steel pipe clamp and the second steel pipe clamp, the telescopic mechanism 1402 of the steel pipe turnover mechanism first drives the turnover mechanism mounting plate, the steel pipe sleeve mounting plate and the like to integrally move backwards.

The purpose of this kind of way is, avoid steel pipe tilting mechanism 14 to influence the placing of steel pipe anchor clamps one, steel pipe anchor clamps two.

I.5. The moving trough body travel driving mechanism drives the moving trough body 1202 to retract backwards. At this time, the first steel pipe clamp 17a and the second steel pipe clamp 17b are combined to form the steel pipe clamp 17.

And the installed vertical steel pipe and the installed transverse steel pipe are respectively positioned in a steel pipe fixing hole 18.

I.6. The two steel pipe conveying mechanisms 4 respectively convey the steel pipes to the scaffold assembling mechanism 9, one of the steel pipe conveying mechanisms 4 conveys the steel pipes from the steel pipe upper part feeding groove 1001, and the process goes to step i.7.

The other steel pipe transfer means 4 feeds the steel pipe from the steel pipe lower feed groove 1002, and proceeds to step I.8.

The process of conveying the steel pipe by the upper part and the bottom part of the steel pipe conveying mechanism 4 in the step i.6 is as follows:

when the steel pipe conveying mechanism 4 is fed into the steel pipe from the upper part of the steel pipe into the groove, the roller groove baffle 424 which is close to the first steel pipe falling passage of the two roller groove baffles extends out, and the roller groove baffle 423 which is far away from the first steel pipe falling passage retracts.

The first push plate 404 first pushes the steel tube on the surface of the first partition plate 402 into the roller groove 421, the power roller starts to work, and the steel tube in the roller groove 421 is conveyed out of the steel tube conveying mechanism through the circular through hole at the upper part.

With the aid of the upper steel pipe gear auxiliary transmission mechanism, the steel pipes smoothly reach the scaffold assembly mechanism 9.

When the steel pipe conveying mechanism 4 needs to be fed into the steel pipe from the lower part of the steel pipe into the groove, the two roller groove baffles retract.

The first push plate 404 pushes the steel tube above the first partition 402 to the first steel tube falling channel 407, the steel tube falls to the surface of the second partition through the first steel tube falling channel, and the second push plate pushes the steel tube on the surface of the second partition to the second steel tube falling channel.

The steel pipe falls to the inclined plane 411 of the guide block from the second steel pipe falling channel 408 and finally reaches the groove 409; the gear transmission mechanism works and transmits the steel pipe in the groove 409 to the outside of the steel pipe transmission mechanism through the circular through hole at the lower part.

Under the assistance of the lower steel pipe gear auxiliary transmission mechanism, the steel pipe smoothly reaches the scaffold assembling mechanism.

I.7. The steel pipe turnover mechanism 14 converts the horizontally arranged steel pipe into a vertically arranged steel pipe, inserts the vertically arranged steel pipe into the steel pipe fixing hole 18 at the top of the steel pipe clamp 17, and then goes to step I.9.

In this step, the steel pipe turning mechanism 14 turns the steel pipe in the following specific process:

in an initial state, the steel pipe sleeve is in a closed state and is horizontally placed; the steel pipe delivered from the upper part of the steel pipe conveying mechanism 4 on one side is delivered into the working box 10 through the upper part of the steel pipe and inserted into the steel pipe sleeve.

Under the drive of steel pipe sleeve mounting plate rotation driving mechanism 1404, steel pipe sleeve mounting plate 1403 and steel pipe sleeve rotate synchronously, and in the rotation process, steel pipe straightening mechanism 1405 extends upwards to realize the straightening of steel pipes.

When the steel pipe is in the vertical state, certain skew still can take place, and two supplementary steel pipe righting mechanisms 1409 draw close to the centre in step this moment, and corresponding support groove support is held up on the upper portion of steel pipe, guarantees that the steel pipe is in vertical state.

I.8. The steel pipe is horizontally inserted into the steel pipe fixing hole 18 of the side portion of the steel pipe clamp from one side, and the process goes to step I.9.

I.9. Under the drive of the fastening mechanism traveling driving mechanism 16, the steel pipe clamp fastening mechanism 15 moves forward to the position of the steel pipe clamp 17, and the steel pipe clamp fastening mechanism 15 screws the bolt 19 on the steel pipe clamp 17 to realize the installation of the steel pipe.

And then, the installation of one position point of the scaffold is completed, the scaffold installation robot retreats backwards, and each working mechanism resets.

I.10. And repeating the steps I.1-I.9 until all the position points on the current working surface are installed.

I.11. And transferring the scaffold mounting robot to another working surface, and repeating the process until the scaffold is built.

The scaffold building process in the embodiment 2 is convenient, the automation degree is high, and the building efficiency is greatly improved.

It should be understood, however, that the description herein of specific embodiments is not intended to limit the invention to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

Claims (5)

1. An automatic installation method of a fastener type steel pipe scaffold is characterized in that,

the installation of the fastener type steel pipe scaffold is realized based on the scaffold installation robot; the scaffold mounting robot comprises a rack, a travelling mechanism, a pipe embracing mechanism, a mounting plate, a steel pipe conveying mechanism and a scaffold assembling mechanism;

the walking mechanism comprises a transverse moving mechanism and a longitudinal moving mechanism; the transverse movement mechanism and the longitudinal movement mechanism are both arranged on the rack and are respectively used for driving the rack to realize movement in a first direction and a second direction;

the first direction and the second direction are two directions which are vertical to each other in a horizontal plane;

the pipe embracing mechanism is arranged on the rack and is configured to be used for realizing the position fixation of the rack after running in place;

the mounting plate is positioned above the rack and extends along the first direction together with the rack;

an installation plate lifting mechanism is arranged between the frame and the installation plate;

a lifting mechanism moving mechanism is arranged at the bottom of the mounting plate lifting mechanism, is mounted on the rack and is configured to drive the mounting plate lifting mechanism to move along the second direction;

the scaffold assembling mechanism and the steel pipe conveying mechanism are arranged on the mounting plate; the two steel pipe conveying mechanisms are respectively positioned on the opposite sides of the scaffold assembling mechanism in the first direction;

the steel pipe conveying mechanism is configured to convey steel pipes to the scaffold assembling mechanism;

the scaffold assembling mechanism comprises a working box, a steel pipe clamp storage groove, a steel pipe and steel pipe clamp assembling groove, a steel pipe clamp hoisting mechanism, a steel pipe overturning mechanism, a steel pipe clamp fastening mechanism and a fastening mechanism walking driving mechanism;

the working box is a square box body with an opening at one side, and the opening of the working box faces to the second direction;

two opposite side plates of the working box along the first direction are respectively provided with a steel pipe upper part feeding groove and a steel pipe lower part feeding groove; wherein, the steel pipe upper part feeding groove and the steel pipe lower part feeding groove are both positioned at the opening of the working box;

the upper steel pipe feeding grooves and the lower steel pipe feeding grooves on the two opposite side plates are respectively arranged in a one-to-one correspondence manner;

the feeding groove at the upper part of the steel pipe and the feeding groove at the lower part of the steel pipe are both U-shaped grooves;

the opening of the steel pipe upper feeding groove faces to the third direction, and the opening of the steel pipe lower feeding groove faces to the second direction; the third direction is a direction perpendicular to the horizontal plane, namely a vertical direction;

the steel pipe clamp storage groove is arranged in the working box and used for storing the steel pipe clamp;

the steel pipe clamp comprises a first steel pipe clamp and a second steel pipe clamp, and when the first steel pipe clamp and the second steel pipe clamp are combined to form the steel pipe clamp, steel pipe fixing holes for accommodating the steel pipes are formed in multiple surfaces of the steel pipe clamp respectively;

the first steel pipe clamp and the second steel pipe clamp are arranged in pairs and in a split mode in the steel pipe clamp storage groove;

the steel pipe and steel pipe clamp assembling groove is positioned in the middle of the opening side of the working box and is arranged on the bottom plate of the working box;

the steel pipe and steel pipe clamp assembling groove comprises a fixed groove body and a movable groove body, wherein the movable groove body is provided with a movable groove body walking driving mechanism which is used for driving the movable groove body to move along a second direction;

the steel pipe clamp hoisting mechanism comprises a steel pipe clamp hoisting clamp and a three-axis motion driving mechanism;

the steel pipe clamp hoisting clamp is arranged on the three-axis motion driving mechanism;

the three-axis motion driving mechanism is used for driving the steel pipe clamp hoisting clamp to move along a first direction, a second direction and a third direction;

the steel pipe clamp hoisting clamp is used for sequentially taking the first steel pipe clamp and the second steel pipe clamp out of the steel pipe clamp storage groove, and correspondingly placing the taken first steel pipe clamp and the taken second steel pipe clamp in the fixed groove body and the movable groove body respectively;

the steel pipe turnover mechanism is arranged in the working box and is positioned at the opening side of the working box;

the steel pipe overturning mechanism is configured to be used for taking a steel pipe from the steel pipe conveying mechanism on one side of the working box along the second direction, overturning the steel pipe and inserting the steel pipe into a steel pipe fixing hole of the steel pipe clamp along the third direction;

the steel pipe to be installed along the second direction is sent into the working box through the lower part of the steel pipe and the groove; the steel pipe which needs to be installed along the third direction is sent into the working box through the upper part of the steel pipe and the groove;

the fastening mechanism walking driving mechanism is arranged on the bottom plate of the working box and extends along the second direction;

the steel pipe clamp fastening mechanism is arranged on the fastening mechanism walking driving mechanism and can move along the second direction, and the steel pipe clamp fastening mechanism is used for fastening a steel pipe and a steel pipe clamp in the steel pipe and steel pipe clamp assembling groove;

the automatic installation method of the fastener type steel pipe scaffold comprises the following steps:

I.1. the transverse movement mechanism firstly drives the rack to travel to a position where steel pipe construction is to be carried out along a first direction of a working surface, and the transverse movement mechanism stops moving; then, the longitudinal movement mechanism drives the rack to move forwards along the second direction of the working surface and gradually approaches the installed vertical steel pipe, and the longitudinal movement mechanism stops moving after reaching the position of the steel pipe;

the pipe holding mechanism holds the installed vertical steel pipe tightly, so that the position of the frame is fixed after the frame runs in place;

I.2. the lifting mechanism moving mechanism firstly drives the mounting plate lifting mechanism to move backwards along a second direction, so that the mounting plate, the steel pipe conveying mechanism and the scaffold assembling mechanism are separated from the steel pipe backwards by a set distance;

then, the mounting plate lifting mechanism acts and drives the mounting plate, the steel pipe conveying mechanism and the scaffold assembling mechanism to ascend to a working height position, and the mounting plate lifting mechanism stops acting;

the lifting mechanism moving mechanism drives the mounting plate lifting mechanism to move forwards to the initial position of the mounting plate lifting mechanism;

I.3. the moving tank body walking driving mechanism drives the moving tank body to be pushed out forwards;

I.4. the steel pipe clamp hoisting mechanism sequentially takes the first steel pipe clamp and the second steel pipe clamp out of the steel pipe clamp storage groove, puts the first steel pipe clamp into the fixed groove body, and puts the second steel pipe clamp into the movable groove body;

I.5. the moving tank body walking driving mechanism drives the moving tank body to retract backwards to the initial position of the moving tank body along the second direction; at the moment, the first steel pipe clamp and the second steel pipe clamp are combined to form a steel pipe clamp;

I.6. the two steel pipe conveying mechanisms respectively convey steel pipes to the scaffold assembling mechanism, one of the steel pipe conveying mechanisms conveys the steel pipes into the steel pipe from the upper part of the steel pipe feeding groove, and the step I.7 is carried out;

the other steel pipe conveying mechanism conveys the steel pipe into the steel pipe conveying groove from the lower part of the steel pipe and goes to step I.8;

I.7. the steel tube turnover mechanism converts the horizontally placed steel tube into a vertically placed steel tube, inserts the vertical steel tube into the steel tube fixing hole at the top of the steel tube clamp, and then turns to step I.9;

I.8. horizontally inserting the steel pipe into the steel pipe fixing hole at the side part of the steel pipe clamp from one side, and turning to step I.9;

I.9. under the drive of the fastening mechanism walking drive mechanism, the steel pipe clamp fastening mechanism moves forwards to the position of the steel pipe clamp, and the steel pipe clamp fastening mechanism screws the bolt on the steel pipe clamp to realize the installation of the steel pipe;

at this point, the installation of one position point of the scaffold is completed, the scaffold installation robot retreats backwards, and each working mechanism resets;

I.10. repeating the steps I.1-I.9 until all the position points on the current working surface are installed;

I.11. and transferring the scaffold mounting robot to another working surface, and repeating the process until the scaffold is built.

2. The automatic installation method of a clip-type steel pipe scaffold according to claim 1,

the steel pipe conveying mechanism comprises a square box body, a first partition plate, a second partition plate, a first push plate, a second push plate, a roller conveying mechanism and a gear conveying mechanism, wherein the first partition plate, the second partition plate, the first push plate, the second push plate, the roller conveying mechanism and the gear conveying mechanism are positioned in the box body;

the first partition plate is arranged on the first side plate of the box body, and a first steel pipe falling channel is arranged between the first partition plate and the second side plate of the box body; the second partition plate is arranged on a second side plate of the box body, and a second steel pipe falling channel is arranged between the second partition plate and the first side plate of the box body;

the first side plate and the second side plate are opposite side plates;

the first partition plate and the second partition plate are both arranged along the horizontal direction, and the first partition plate is positioned above the second partition plate;

the first push plate is positioned above the first partition plate, and the pushing direction of the first push plate faces the first steel pipe falling channel; the second push plate is positioned above the second partition plate, and the pushing direction of the second push plate faces the second steel pipe falling channel;

the roller conveying mechanism is arranged on the first partition plate; the roller transmission mechanism comprises a roller groove arranged along a first direction and a plurality of rollers arranged in the roller groove; part of the rollers are power rollers, and part of the rollers are unpowered rollers;

the opposite sides of the roller groove are respectively provided with a roller groove baffle;

the extending direction of each roller groove baffle is the same as the extending direction of the roller groove, a baffle mounting groove is formed in the position, corresponding to each roller groove baffle, of the first partition plate, and the roller groove baffles are located in the corresponding baffle mounting grooves;

each baffle mounting groove is internally provided with a telescopic mechanism connected with the bottom of the corresponding roller groove baffle;

a semi-circular arc-shaped groove is formed in a bottom plate of the box body, wherein the extending direction of the groove is parallel to the extending direction of the first push plate;

the gear transmission mechanism is arranged at the groove and used for conveying the steel pipe in the groove;

circular through holes are respectively formed in the other opposite side plate of the box body corresponding to the roller groove and the groove, wherein the opposite side plate is adjacent to the first side plate and the second side plate;

a guide block is arranged on a bottom plate of the box body and is positioned right below the steel pipe falling channel II;

an inclined plane which guides towards the groove is arranged on the guide block;

a group of upper steel pipe gear auxiliary transmission mechanisms are arranged at the upper steel pipe feeding groove of the working box, and are aligned with the roller groove and the upper steel pipe feeding groove in the first direction;

a group of lower steel pipe gear auxiliary transmission mechanisms are arranged at the position of the steel pipe upper feeding groove of the working box, and are aligned with the groove on the bottom plate in the box body and the steel pipe lower feeding groove in the first direction;

in the step I.6, when the steel pipe conveying mechanism is conveyed into the steel pipe from the upper part of the steel pipe into the groove, the roller groove baffle plate close to the first steel pipe falling channel of the two roller groove baffle plates extends out, and the roller groove baffle plate far away from the first steel pipe falling channel retracts;

the first push plate firstly pushes the steel pipe on the surface of the first partition plate into the roller groove, the power roller starts to work, and the steel pipe in the roller groove is conveyed out of the steel pipe conveying mechanism through the circular through hole at the upper part;

under the assistance of the upper steel pipe gear auxiliary transmission mechanism, the steel pipe smoothly reaches the scaffold assembly mechanism;

when the steel pipe conveying mechanism needs to be conveyed into the steel pipe from the lower part of the steel pipe into the groove, the two roller groove baffles retract;

the first push plate pushes the steel pipe above the first partition plate to the first steel pipe falling channel, the steel pipe falls to the surface of the second partition plate through the first steel pipe falling channel, and the second push plate pushes the steel pipe on the surface of the second partition plate to the second steel pipe falling channel;

the steel pipe falls onto the inclined plane of the guide block from the steel pipe falling channel II and finally reaches the groove of the bottom plate; the gear transmission mechanism works and transmits the steel pipe in the groove to the outside of the steel pipe transmission mechanism through the circular through hole at the lower part;

under the assistance of the lower steel pipe gear auxiliary transmission mechanism, the steel pipe smoothly reaches the scaffold assembling mechanism.

3. The automatic installation method of a clip-type steel pipe scaffold according to claim 1,

the steel pipe clamp hoisting clamp comprises a clamp mounting plate, a steel pipe clamp sucking tool and a steel pipe clamp secondary sucking tool;

the steel pipe clamp sucking tool and the steel pipe clamp secondary sucking tool are both arranged on the clamp mounting plate, and are symmetrical in structure;

the steel pipe clamp suction tool and the steel pipe clamp secondary suction tool both adopt electromagnet structures, and each electromagnet is formed by sequentially connecting a strip-shaped electromagnet section, a semicircular strip-shaped electromagnet section and another strip-shaped electromagnet section;

ceramic plates are arranged between the steel pipe clamp suction tool and the steel pipe clamp secondary suction tool and are separated by the ceramic plates;

in the step I.4, the three-axis motion driving mechanism firstly drives the steel pipe clamp hoisting clamp to reach the steel pipe clamp storage groove and fall to the placing position of a group of steel pipe clamps in the steel pipe clamp storage groove;

at the moment, the steel pipe clamp suction tool is attached to the first steel pipe clamp, and the second steel pipe clamp suction tool is attached to the second steel pipe clamp;

the steel pipe clamp sucking tool is firstly electrified and sucks a first steel pipe clamp, and the first steel pipe clamp is conveyed into the fixed groove body by the steel pipe clamp hoisting clamp under the driving of the three-axis motion driving mechanism;

under the drive of the three-axis motion driving mechanism, the steel pipe clamp hoisting clamp moves to the steel pipe clamp storage groove again and falls to the placing position of the group of steel pipe clamps in the steel pipe clamp storage groove;

at the moment, the second steel pipe clamp suction tool is attached to the second steel pipe clamp; and the second steel pipe clamp suction tool is electrified and sucks the second steel pipe clamp, and the second steel pipe clamp is conveyed into the moving groove body by the steel pipe clamp hoisting clamp under the driving of the three-axis motion driving mechanism.

4. The automatic installation method of a clip-type steel pipe scaffold according to claim 1,

the steel pipe turnover mechanism comprises a turnover mechanism mounting plate, a telescopic mechanism, a steel pipe sleeve mounting plate rotation driving mechanism, a steel pipe centering mechanism and an auxiliary steel pipe centering mechanism;

the telescopic mechanism is fixedly installed, and the installation plate of the turnover mechanism adopts a door-shaped structure; the telescopic mechanism is connected with the turnover mechanism mounting plate and is used for driving the turnover mechanism mounting plate to move along a second direction;

the steel pipe sleeve mounting plate rotation driving mechanism is arranged on the turnover mechanism mounting plate and is positioned at a different side from the telescopic mechanism;

the steel pipe sleeve mounting plate is connected to the steel pipe sleeve mounting plate rotation driving mechanism;

the steel pipe sleeve comprises two semicircular steel pipe sleeve bodies, and the middle part of each steel pipe sleeve body is hinged with the steel pipe mounting plate;

an electric telescopic rod is arranged between the steel pipe sleeve mounting plate and each steel pipe sleeve body, wherein one end of each electric telescopic rod is hinged to the steel pipe sleeve mounting plate, and the other end of each electric telescopic rod is hinged to the corresponding steel pipe sleeve body;

the steel pipe centralizing mechanism is arranged on the turnover mechanism mounting plate and is positioned on the same side of the turnover mechanism mounting plate as the steel pipe sleeve;

the steel pipe righting mechanism comprises an electric telescopic rod and a supporting groove bracket;

the electric telescopic rod of the steel pipe righting mechanism extends along the third direction, and the support groove bracket is hinged to the end part of the electric telescopic rod;

two groups of auxiliary steel pipe centralizing mechanisms are arranged on the top plate of the working box; the two auxiliary steel pipe centralizing mechanisms are respectively positioned at the opposite end parts of the working box top plate along the first direction and are oppositely arranged;

each auxiliary steel pipe centering mechanism comprises an auxiliary centering mechanism moving mechanism, an electric telescopic rod and a supporting groove bracket;

the auxiliary righting mechanism moving mechanism is arranged along a second direction;

an electric telescopic rod of the auxiliary steel pipe centering mechanism is arranged on the auxiliary centering mechanism moving mechanism and faces to a first direction; the support groove bracket of the auxiliary steel pipe righting mechanism is hinged on an electric telescopic rod of the auxiliary steel pipe righting mechanism;

in the step I.7, the steel pipe overturning mechanism overturns the steel pipe in the following specific process:

in an initial state, the steel pipe sleeve is in a closed state and is horizontally placed; the steel pipe sent out from the upper part of the steel pipe conveying mechanism on one side is sent into the working box through the steel pipe upper part sending groove and is inserted into the steel pipe sleeve;

the steel pipe sleeve mounting plate and the steel pipe sleeve synchronously rotate under the driving of the steel pipe sleeve mounting plate rotation driving mechanism, and the steel pipe centering mechanism gradually extends upwards in the rotation process to realize centering on the steel pipe;

when the steel pipe is in a vertical state, certain offset still can occur, at the moment, the two auxiliary steel pipe centering mechanisms are synchronously close to the middle, and the corresponding support groove supports are centered on the upper portion of the steel pipe, so that the steel pipe is ensured to be in a vertical state.

5. The automatic installation method of a clip-type steel pipe scaffold according to claim 4,

in the step i.4, before the steel pipe clamp hoisting mechanism takes the first steel pipe clamp and the second steel pipe clamp, the telescopic mechanism of the steel pipe turnover mechanism firstly drives the turnover mechanism mounting plate, the steel pipe sleeve and the steel pipe sleeve mounting plate to integrally move backwards along the second direction.

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