CN113548601A - Auxiliary moving supporting device for prefabricated part for constructional engineering - Google Patents

Abstract

The invention discloses a prefabricated part auxiliary moving supporting device for constructional engineering, which has the beneficial effects that a lifting and pulling structure is used for pushing and pulling and fine tuning a prefabricated part in the horizontal direction, a horizontal extrusion fixing fine tuning assembly is used for carrying out extrusion fixing and horizontal fine tuning in the horizontal direction, and a telescopic moving fixing structure is used for carrying out telescopic fixing and negative pressure adsorption fixing, so that the effects of supporting the telescopic movement in a telescopic moving assembly and fixing the whole device by negative air pressure are achieved.

Description

Auxiliary moving supporting device for prefabricated part for constructional engineering

Technical Field

The invention relates to the technical field of constructional engineering, in particular to a prefabricated member auxiliary moving supporting device for constructional engineering.

Background

The concrete prefabricated part is widely applied to the fields of buildings, traffic, water conservancy and the like, plays an important role in national economy, such as a prefabricated reinforced concrete column foundation, a prefabricated steel structure steel column foundation, a street lamp billboard column reinforced concrete foundation and a prefabricated floor slab, the existing prefabricated part carrying process is to horizontally lift a plate, and the prefabricated part needs to be carried and rotated manually.

Disclosure of Invention

The technical scheme of the invention for realizing the aim is as follows: a prefabricated member auxiliary moving support device for construction engineering comprises: the lifting support bracket is mounted at the top end of the concave movable support block, a lifting structure is mounted on the lifting support bracket, and a telescopic movable fixing structure is mounted in the concave movable support block;

the lifting structure comprises: the device comprises two pairs of lifting driving machines, two pairs of lifting driving bevel gears, two pairs of lifting transmission bevel gears, two pairs of lifting threaded pipes, two pairs of lifting threaded rods, a lifting concave plate, two pairs of auxiliary winches and a horizontal extrusion fixing fine adjustment assembly;

the two pairs of lifting threaded rods are respectively horizontally and parallelly arranged on the side wall of the lifting support bracket through a bearing, the two pairs of lifting threaded pipes are horizontally and parallelly inserted in the lifting concave plate through the bearing, and two pairs of the lifting screw pipes are respectively sleeved on the outer sides of two pairs of the lifting screw rods, two pairs of the lifting driving machines are horizontally and parallelly arranged on the lifting supporting bracket, two pairs of the lifting driving bevel gears are respectively arranged at the driving ends of the two pairs of the lifting driving machines, two pairs of the lifting driving bevel gears are respectively arranged on the two pairs of the lifting screw rods, and two pairs of the lifting transmission bevel gears are respectively engaged with two pairs of the lifting driving bevel gears, two pairs of the auxiliary winches are respectively horizontally arranged on the lifting support bracket, and the other ends of the two pairs of auxiliary winches are connected to the lifting concave plate, and the horizontal extrusion fixing fine-tuning assembly is installed on the inner side of the lifting concave plate.

Preferably, the telescopic moving fixing structure comprises: the lifting device comprises two pairs of concave lifting limiting blocks, two pairs of lifting support driving machines, two pairs of lifting support driving bevel gears, two pairs of lifting support transmission bevel gears, two pairs of lifting support threaded pipes, two pairs of lifting support threaded rods, two pairs of lifting support concave cylindrical blocks and a telescopic moving assembly;

two pairs of concave lifting limiting blocks are arranged on the inner sides of the concave movable supporting blocks in parallel, two pairs of lifting support driving machines are respectively arranged on the top ends of the two pairs of concave lifting limiting blocks, two pairs of lifting support threaded pipes are respectively inserted into the two pairs of concave lifting limiting blocks through bearings, two pairs of lifting support threaded rods are respectively movably inserted into the inner sides of the two pairs of lifting support threaded pipes, a plurality of lifting support driving bevel gears are respectively arranged at the driving ends of the two pairs of lifting support driving machines, two pairs of lifting support transmission bevel gears are respectively arranged on the outer sides of the two pairs of lifting support threaded pipes, the two pairs of lifting support transmission bevel gears are respectively engaged with the two pairs of lifting support driving bevel gears, and two pairs of lifting support concave cylindrical blocks are respectively arranged at the bottom ends of the two pairs of lifting support threaded rods through bearings, the telescopic moving assembly is arranged on the inner side of the concave moving bearing block.

Preferably, the horizontal pressing fixing fine-tuning assembly comprises: the horizontal extrusion device comprises a pair of concave horizontal extrusion blocks, a plurality of horizontal extrusion concave wheels, a plurality of horizontal extrusion threaded rods, a plurality of horizontal extrusion threaded pipes, a plurality of horizontal extrusion chain wheels, a pair of horizontal extrusion chains and a pair of horizontal extrusion driving machines;

horizontal extrusion grooves are respectively formed in the side walls of the two sides of the lifting concave plate, a pair of concave horizontal extrusion blocks are respectively movably inserted in the inner sides of the pair of horizontal extrusion grooves, a plurality of horizontal extrusion threaded pipes are respectively inserted in the two sides of the lifting concave plate through bearings, a plurality of horizontal extrusion threaded rods are respectively movably inserted in the inner sides of the plurality of horizontal extrusion threaded pipes, the plurality of horizontal extrusion threaded rods are respectively connected to the pair of concave horizontal extrusion blocks through bearings, a plurality of horizontal extrusion concave wheels are respectively vertically inserted in the inner sides of the pair of concave horizontal extrusion blocks through bearings, a pair of horizontal extrusion drivers are respectively installed on the two sides of the lifting concave plate, a plurality of horizontal extrusion chain wheels are respectively installed on the outer sides of the plurality of horizontal extrusion threaded pipes and the driving ends of the pair of horizontal extrusion drivers, the pair of horizontal extrusion chains is respectively sleeved on the plurality of horizontal extrusion chain wheels, and the movable extrusion part is arranged on the inner sides of the plurality of horizontal extrusion concave wheels.

Preferably, the telescopic moving assembly comprises: the device comprises a pair of driving shafts, a pair of rotating shafts, two pairs of moving wheels, two pairs of concave circular ring blocks, two pairs of telescopic limiting T-shaped rods, a pair of scissor brackets and two pairs of telescopic spring columns;

the novel telescopic device is characterized in that two pairs of circular arc moving grooves are formed in the concave moving supporting block, locking openings are formed in the inner sides of the two pairs of circular arc moving grooves respectively, one pair of driving shafts are inserted into the concave moving supporting block through bearings, two pairs of concave circular ring blocks are installed on two sides of the rotating shaft respectively, two pairs of concave circular ring blocks are movably inserted into the inner sides of the two pairs of circular arc moving grooves respectively, one pair of scissor type supports are installed on one pair of driving shafts and one pair of rotating shafts respectively, two pairs of telescopic spring columns are installed on one pair of scissor type supports respectively, telescopic grooves are formed in the two pairs of locking openings respectively, two pairs of telescopic limiting T-shaped rods are movably inserted into the inner sides of the two pairs of telescopic grooves respectively, and two pairs of moving wheels are installed on two sides of the driving shafts respectively.

Preferably, the outer sides of the plurality of horizontal concave extrusion blocks are respectively provided with an extrusion rubber pad.

Preferably, a plurality of ball grooves are formed in the two pairs of arc moving grooves, and moving balls are arranged in the ball grooves respectively.

Preferably, the bottom end of the concave movable supporting block is provided with a rubber pad.

Preferably, the two pairs of concave lifting limiting blocks are internally provided with a pressure sensor respectively.

Preferably, a plurality of lifting slide ways are arranged on the lifting support bracket, a plurality of lifting slide blocks are arranged on the lifting concave plate, and the plurality of lifting slide blocks are respectively movably inserted in the plurality of lifting slide ways.

Preferably, an infrared distance meter is arranged on the outer side of the concave movable supporting block.

The auxiliary moving supporting device for the prefabricated part for the building engineering, which is manufactured by the technical scheme of the invention, is used for pushing, pulling and fine-tuning the prefabricated part in the horizontal direction through the lifting and pulling structure, meanwhile, the horizontal extrusion fixing fine-tuning component is used for carrying out extrusion fixing and horizontal fine-tuning in the horizontal direction, and the telescopic fixing and negative pressure adsorption fixing are carried out through the telescopic moving fixing structure, so that the effects of supporting the telescopic movement in the telescopic moving component and fixing the negative pressure when the whole device is fixed are achieved.

Drawings

Fig. 1 is a schematic front view of a prefabricated member auxiliary moving support device for construction engineering according to the present invention.

Fig. 2 is a schematic side view of a prefabricated member auxiliary moving support device for construction engineering according to the present invention.

Fig. 3 is an enlarged view of the structure of the portion "a" in fig. 1.

Fig. 4 is an enlarged view of the structure of the portion "B" in fig. 1.

Fig. 5 is an enlarged view of the structure of the "C" portion in fig. 1.

In the figure: 1. a concave movable support block; 2. a lifting support bracket; 3. a lift drive; 4. lifting and driving the bevel gear; 5. lifting transmission bevel gears; 6. lifting the threaded pipe; 7. lifting a threaded rod; 8. lifting the concave plate; 9. an auxiliary hoist; 10. a concave lifting limiting block; 11. a lifting support driving machine; 12. lifting support driving bevel gears; 13. lifting support transmission bevel gears; 14. lifting and supporting the threaded pipe; 15. lifting the support threaded rod; 16. lifting and supporting the concave cylindrical block; 17. horizontally extruding the concave wheel; 18. horizontally extruding the threaded rod; 19. horizontally extruding the threaded pipe; 20. horizontally extruding the chain wheel; 21. horizontally extruding the chain; 22. a horizontal extrusion driver.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings, as shown in fig. 1 to 5, a prefabricated member auxiliary moving support device for construction engineering, comprising: the lifting device comprises a concave movable supporting block 1 and a lifting supporting bracket 2, wherein the lifting supporting bracket 2 is installed at the top end of the concave movable supporting block 1, a lifting structure is installed on the lifting supporting bracket 2, and a telescopic movable fixing structure is installed in the concave movable supporting block 1; the lifting structure comprises: the device comprises two pairs of lifting driving machines 3, two pairs of lifting driving bevel gears 4, two pairs of lifting transmission bevel gears 5, two pairs of lifting threaded pipes 6, two pairs of lifting threaded rods 7, a lifting concave plate 8, two pairs of auxiliary winches 9 and a horizontal extrusion fixing fine adjustment assembly; two pairs of lifting threaded rods 7 are respectively horizontally and parallelly installed on the side wall of the lifting support bracket 2 through bearings, two pairs of lifting threaded pipes 6 are horizontally and parallelly inserted in the lifting concave plate 8 through bearings, the two pairs of lifting threaded pipes 6 are respectively sleeved on the outer sides of the two pairs of lifting threaded rods 7, two pairs of lifting driving machines 3 are horizontally and parallelly installed on the lifting support bracket 2, two pairs of lifting driving bevel gears 4 are respectively installed at the driving ends of the two pairs of lifting driving machines 3, two pairs of lifting transmission bevel gears 5 are respectively installed on the two pairs of lifting threaded rods 7, the two pairs of lifting transmission bevel gears 5 are respectively in gear engagement with the two pairs of lifting driving bevel gears 4, two pairs of auxiliary winches 9 are respectively and horizontally installed on the lifting support bracket 2, and the other ends of the two pairs of auxiliary winches 9 are connected to the lifting concave plate 8, the horizontal extrusion fixing fine-tuning assembly is arranged on the inner side of the lifting concave plate 8; the telescopic movable fixing structure comprises: the lifting device comprises two pairs of concave lifting limiting blocks 10, two pairs of lifting support driving machines 11, two pairs of lifting support driving bevel gears 12, two pairs of lifting support transmission bevel gears 13, two pairs of lifting support threaded pipes 14, two pairs of lifting support threaded rods 15, two pairs of lifting support concave cylindrical blocks 16 and a telescopic moving assembly; two pairs of the concave lifting limiting blocks 10 are arranged on the inner side of the concave movable supporting block 1 in parallel, two pairs of the lifting support driving machines 11 are respectively arranged on the top ends of the two pairs of the concave lifting limiting blocks 10, two pairs of the lifting support threaded pipes 14 are respectively inserted into the two pairs of the concave lifting limiting blocks 10 through bearings, two pairs of the lifting support threaded rods 15 are respectively movably inserted into the inner sides of the two pairs of the lifting support threaded pipes 14, a plurality of the lifting support driving bevel gears 12 are respectively arranged on the driving ends of the two pairs of the lifting support driving machines 11, two pairs of the lifting support transmission bevel gears 13 are respectively arranged on the outer sides of the two pairs of the lifting support threaded pipes 14, the two pairs of the lifting support transmission bevel gears 13 are respectively in gear engagement with the two pairs of the lifting support driving bevel gears 12, and two pairs of the concave lifting support cylindrical blocks 16 are respectively arranged on the bottom ends of the two pairs of the lifting support threaded rods 15 through bearings, the telescopic moving assembly is arranged on the inner side of the concave moving bearing block; the horizontal extrusion fixing fine adjustment assembly comprises: a pair of concave horizontal extrusion blocks, a plurality of horizontal extrusion concave wheels 17, a plurality of horizontal extrusion threaded rods 18, a plurality of horizontal extrusion threaded pipes 19, a plurality of horizontal extrusion chain wheels 20, a pair of horizontal extrusion chains 21 and a pair of horizontal extrusion driving machines 22; horizontal extrusion grooves are respectively formed in the side walls of the two sides of the lifting concave plate 8, a pair of concave horizontal extrusion blocks are respectively movably inserted into the inner sides of the pair of horizontal extrusion grooves, a plurality of horizontal extrusion threaded pipes 19 are respectively inserted into the two sides of the lifting concave plate 8 through bearings, a plurality of horizontal extrusion threaded rods 18 are respectively movably inserted into the inner sides of the plurality of horizontal extrusion threaded pipes 19, the plurality of horizontal extrusion threaded rods 18 are respectively connected to the pair of concave horizontal extrusion blocks through bearings, a plurality of horizontal extrusion concave wheels 17 are respectively vertically inserted into the inner sides of the pair of concave horizontal extrusion blocks through bearings, a pair of horizontal extrusion drivers 22 are respectively installed on the two sides of the lifting concave plate 8, a plurality of horizontal extrusion chain wheels 20 are respectively installed on the outer sides of the plurality of horizontal extrusion threaded pipes 19 and the driving ends of the pair of horizontal extrusion drivers 22, the pair of horizontal extrusion chains 21 are respectively sleeved on the plurality of horizontal extrusion chain wheels 20, and the movable extrusion parts are arranged on the inner sides of the plurality of horizontal extrusion concave wheels 17; the telescopic moving component comprises: the device comprises a pair of driving shafts, a pair of rotating shafts, two pairs of moving wheels, two pairs of concave circular ring blocks, two pairs of telescopic limiting T-shaped rods, a pair of scissor brackets and two pairs of telescopic spring columns; two pairs of circular arc moving grooves are formed in the concave moving support block 1, locking openings are formed in the inner sides of the two pairs of circular arc moving grooves respectively, a pair of driving shafts are inserted into the concave moving support block 1 through bearings, two pairs of concave circular ring blocks are installed on two sides of a pair of rotating shafts respectively, two pairs of concave circular ring blocks are movably inserted into the inner sides of the two pairs of circular arc moving grooves respectively, a pair of scissor type supports are installed on the pair of driving shafts and the pair of rotating shafts respectively, two pairs of telescopic spring columns are installed on the pair of scissor type supports respectively, telescopic grooves are formed in the two pairs of locking openings respectively, two pairs of telescopic limiting T-shaped rods are movably inserted into the inner sides of the two pairs of telescopic grooves respectively, and two pairs of moving wheels are installed on two sides of the pair of driving shafts respectively; extrusion rubber pads are respectively arranged on the outer sides of the horizontal concave extrusion blocks; a plurality of ball grooves are formed in the two pairs of arc moving grooves, and moving balls are arranged in the ball grooves respectively; the bottom end of the concave movable supporting block 1 is provided with a rubber pad; pressure sensors are respectively arranged in the two pairs of concave lifting limiting blocks 10; a plurality of lifting slide ways are arranged on the lifting support bracket 2, a plurality of lifting slide blocks are arranged on the lifting concave plate 8, and the plurality of lifting slide blocks are respectively and movably inserted in the plurality of lifting slide ways; and an infrared distance meter is arranged on the outer side of the concave movable supporting block 1.

The present embodiment is characterized by comprising: the lifting support bracket is arranged at the top end of the concave movable support block, a lifting structure is arranged on the lifting support bracket, and a telescopic movable fixing structure is arranged in the concave movable support block; the lifting structure comprises: the device comprises two pairs of lifting driving machines, two pairs of lifting driving bevel gears, two pairs of lifting transmission bevel gears, two pairs of lifting threaded pipes, two pairs of lifting threaded rods, a lifting concave plate, two pairs of auxiliary winches and a horizontal extrusion fixing fine adjustment assembly; two pairs of lifting threaded rods are horizontally and parallelly arranged on the side wall of the lifting support bracket through bearings respectively, two pairs of lifting threaded pipes are horizontally and parallelly inserted in the lifting concave plate through bearings, the two pairs of lifting threaded pipes are sleeved on the outer sides of the two pairs of lifting threaded rods respectively, two pairs of lifting driving machines are horizontally and parallelly arranged on the lifting support bracket, two pairs of lifting driving bevel gears are arranged at the driving ends of the two pairs of lifting driving machines respectively, two pairs of lifting transmission bevel gears are arranged on the two pairs of lifting threaded rods respectively and are engaged with the two pairs of lifting driving bevel gears respectively, two pairs of auxiliary winches are horizontally arranged on the lifting support bracket respectively, the other ends of the two pairs of auxiliary winches are connected to the lifting concave plate, and a horizontal extrusion fixing fine adjustment assembly is arranged on the inner side of the lifting concave plate; carry out the push-and-pull and the fine setting on the horizontal direction with the prefab through lifting and drawing the structure, carry out the fixed fine setting subassembly of horizontal extrusion and carry out the fixed and horizontal fine setting of extrusion on the horizontal direction through the fixed fine setting subassembly of horizontal extrusion simultaneously, through flexible removal fixed knot structure, it is fixed to stretch out and draw back and the negative pressure adsorbs fixedly to reach and support the flexible effect that negative pressure when whole device is fixed in the removal subassembly that will stretch out and draw back.

All the electrical components in the present application are connected with the power supply adapted to the electrical components through the wires, and an appropriate controller should be selected according to actual conditions to meet the control requirements, and specific connection and control sequences should be obtained.

Example (b): the whole device is driven to move by two pairs of moving wheels, the two pairs of lifting support driving machines 11 are operated to respectively drive the lifting support driving bevel gears 12 on the driving ends of the two pairs of lifting support driving machines 11 to rotate, the two pairs of lifting support driving bevel gears 12 respectively drive the lifting support transmission bevel gears 13 engaged with the lifting support driving bevel gears to rotate, the two pairs of lifting support transmission bevel gears 13 respectively drive the support threaded pipes on the lifting support driving bevel gears to rotate, the two pairs of lifting support threaded pipes respectively drive the lifting support threaded rods 15 in the lifting support driving bevel gears to descend, so that the two pairs of lifting support concave cylindrical blocks 16 on the lifting support driving bevel gears are respectively driven by the two pairs of lifting support threaded rods 15 to be contacted with the ground, thereby realizing the support of the concave movable supporting block 1, enabling the two pairs of telescopic limiting T-shaped telescopic circular ring blocks to be telescopic back into the telescopic grooves, and enabling the two pairs of concave circular ring blocks to move the inner sides of two pairs of circular arc moving grooves in the two pairs of locking holes, two pairs of concave circular ring blocks move along the inner sides of two pairs of circular arc moving grooves, the two pairs of concave circular ring blocks are moved to the inner sides of the other two pairs of locking openings, so that the rotating shafts on the two pairs of concave circular ring blocks are moved to be horizontally parallel to the driving shaft, the two pairs of moving wheels are moved to be lifted, then two pairs of lifting support driving machines 11 are operated in reverse directions, two pairs of lifting support threaded rods 15 are contracted back to the inner sides of the concave lifting limiting blocks 10, meanwhile, the air pressure in the two pairs of concave lifting limiting blocks 10 is changed, the outside air pressure is larger than the two pairs of concave lifting limiting blocks 10, the concave moving supporting block 1 is extruded and fixed, meanwhile, a pair of horizontal extrusion driving machines 22 in the horizontal extrusion fixing and fine-adjustment assembly are operated, the horizontal extrusion chain wheels 20 on the driving ends of the pair of horizontal extrusion driving machines 22 are respectively driven to rotate, and the horizontal extrusion threaded pipes 19 on the horizontal extrusion driving machines are respectively driven to rotate by a plurality of horizontal extrusion chain wheels 20, the horizontal extrusion threaded rods 18 in the horizontal extrusion threaded pipes are respectively driven to rotate by the horizontal extrusion threaded pipes 19, a pair of concave horizontal extrusion blocks on the horizontal extrusion threaded pipes 18 are respectively driven by the horizontal extrusion threaded pipes 18, a plurality of horizontal extrusion concave wheels 17 on the horizontal extrusion blocks are respectively driven by the concave horizontal extrusion blocks, so that the horizontal extrusion concave wheels 17 respectively and relatively move horizontally, the prefabricated part is extruded and fixed, two pairs of lifting driving helical gears 3 are respectively driven to rotate by the two pairs of lifting driving helical gears 4 on the two pairs of lifting driving gears 3, the lifting driving helical gears 5 engaged with the lifting driving helical gears 4 are respectively driven to rotate by the two pairs of lifting driving helical gears 4, the lifting threaded rods 7 on the lifting driving helical gears 5 are respectively driven to rotate by the two pairs of rotating lifting threaded pipes 7, make two pairs of lift screwed pipe 6 drive the concave template 8 of lift on it respectively for the concave template 8 of lift goes up and down, thereby reach the prefab after fixing the horizontal extrusion, go up and down concave template 8 through two pairs of supplementary hoists 9 simultaneously, a pair of horizontal extrusion driving machine 22 carries out the micro-motion, thereby reach the position that changes the prefab in the horizontal direction, carry out the fine setting on the vertical direction with the prefab through going up and down to draw the structure simultaneously, thereby reach and finely tune the prefab.

Preferably, the telescopic moving fixing structure further comprises: the lifting device comprises two pairs of concave lifting limiting blocks 10, two pairs of lifting support driving machines 11, two pairs of lifting support driving bevel gears 12, two pairs of lifting support transmission bevel gears 13, two pairs of lifting support threaded pipes 14, two pairs of lifting support threaded rods 15, two pairs of lifting support concave cylindrical blocks 16 and a telescopic moving assembly;

two pairs of the concave lifting limiting blocks 10 are arranged on the inner side of the concave movable supporting block 1 in parallel, two pairs of the lifting support driving machines 11 are respectively arranged on the top ends of the two pairs of the concave lifting limiting blocks 10, two pairs of the lifting support threaded pipes 14 are respectively inserted into the two pairs of the concave lifting limiting blocks 10 through bearings, two pairs of the lifting support threaded rods 15 are respectively movably inserted into the inner sides of the two pairs of the lifting support threaded pipes 14, a plurality of the lifting support driving bevel gears 12 are respectively arranged on the driving ends of the two pairs of the lifting support driving machines 11, two pairs of the lifting support transmission bevel gears 13 are respectively arranged on the outer sides of the two pairs of the lifting support threaded pipes 14, the two pairs of the lifting support transmission bevel gears 13 are respectively in gear engagement with the two pairs of the lifting support driving bevel gears 12, and two pairs of the concave lifting support cylindrical blocks 16 are respectively arranged on the bottom ends of the two pairs of the lifting support threaded rods 15 through bearings, the telescopic moving assembly is arranged on the inner side of the concave moving bearing block.

Preferably, the horizontal pressing fixing fine-tuning assembly further comprises: a pair of concave horizontal extrusion blocks, a plurality of horizontal extrusion concave wheels 17, a plurality of horizontal extrusion threaded rods 18, a plurality of horizontal extrusion threaded pipes 19, a plurality of horizontal extrusion chain wheels 20, a pair of horizontal extrusion chains 21 and a pair of horizontal extrusion driving machines 22;

horizontal extrusion grooves are respectively formed in the side walls of the two sides of the lifting concave plate 8, a pair of concave horizontal extrusion blocks are respectively movably inserted into the inner sides of the pair of horizontal extrusion grooves, a plurality of horizontal extrusion threaded pipes 19 are respectively inserted into the two sides of the lifting concave plate 8 through bearings, a plurality of horizontal extrusion threaded rods 18 are respectively movably inserted into the inner sides of the plurality of horizontal extrusion threaded pipes 19, the plurality of horizontal extrusion threaded rods 18 are respectively connected to the pair of concave horizontal extrusion blocks through bearings, a plurality of horizontal extrusion concave wheels 17 are respectively vertically inserted into the inner sides of the pair of concave horizontal extrusion blocks through bearings, a pair of horizontal extrusion drivers 22 are respectively installed on the two sides of the lifting concave plate 8, a plurality of horizontal extrusion chain wheels 20 are respectively installed on the outer sides of the plurality of horizontal extrusion threaded pipes 19 and the driving ends of the pair of horizontal extrusion drivers 22, the pair of horizontal extrusion chains 21 are respectively sleeved on the plurality of horizontal extrusion chain wheels 20, and the movable extrusion parts are arranged on the inner sides of the plurality of horizontal extrusion concave wheels 17.

Preferably, the telescopic moving assembly further comprises: the device comprises a pair of driving shafts, a pair of rotating shafts, two pairs of moving wheels, two pairs of concave circular ring blocks, two pairs of telescopic limiting T-shaped rods, a pair of scissor brackets and two pairs of telescopic spring columns;

two pairs of circular arc moving grooves are formed in the concave moving support block 1, locking openings are formed in the inner sides of the circular arc moving grooves respectively, one pair of circular arc moving grooves are formed in the concave moving support block 1 in a inserted mode through bearings, two pairs of concave circular ring blocks are installed on two sides of the rotating shaft respectively, two pairs of concave circular ring blocks are movably inserted in the inner sides of the two pairs of circular arc moving grooves respectively, one pair of scissor-type supports are installed on one pair of the driving shaft and one pair of the rotating shaft respectively, two pairs of telescopic spring columns are installed on one pair of scissor-type supports respectively, telescopic grooves are formed in the two pairs of locking openings respectively, two pairs of telescopic limiting T-shaped rods are movably inserted in the inner sides of the two pairs of telescopic grooves respectively, and two pairs of moving wheels are installed on two sides of the driving shaft respectively.

Preferably, the outer sides of the plurality of horizontal concave-type extrusion blocks are respectively provided with an extrusion rubber pad.

Preferably, a plurality of ball grooves are formed in the two pairs of arc moving grooves, and moving balls are respectively arranged in the ball grooves.

Preferably, the bottom end of the concave movable supporting block 1 is provided with a rubber pad.

As a preferable scheme, further, pressure sensors are respectively arranged in the two pairs of concave lifting limiting blocks 10.

As a preferable scheme, furthermore, a plurality of lifting slide ways are arranged on the lifting support frame 2, a plurality of lifting slide blocks are arranged on the lifting concave plate 8, and the plurality of lifting slide blocks are respectively and movably inserted into the plurality of lifting slide ways.

Preferably, an infrared distance meter is further arranged outside the concave movable supporting block 1.

The technical solutions described above only represent the preferred technical solutions of the present invention, and some possible modifications to some parts of the technical solutions by those skilled in the art all represent the principles of the present invention, and fall within the protection scope of the present invention.

Claims (10)

1. A prefabricated member auxiliary moving support device for construction engineering comprises: the lifting support structure comprises a concave movable support block and a lifting support bracket, and is characterized in that the lifting support bracket is mounted at the top end of the concave movable support block, a lifting structure is mounted on the lifting support bracket, and a telescopic movable fixing structure is mounted in the concave movable support block;

the lifting structure comprises: the device comprises two pairs of lifting driving machines, two pairs of lifting driving bevel gears, two pairs of lifting transmission bevel gears, two pairs of lifting threaded pipes, two pairs of lifting threaded rods, a lifting concave plate, two pairs of auxiliary winches and a horizontal extrusion fixing fine adjustment assembly;

the two pairs of lifting threaded rods are respectively horizontally and parallelly arranged on the side wall of the lifting support bracket through a bearing, the two pairs of lifting threaded pipes are horizontally and parallelly inserted in the lifting concave plate through the bearing, and two pairs of the lifting screw pipes are respectively sleeved on the outer sides of two pairs of the lifting screw rods, two pairs of the lifting driving machines are horizontally and parallelly arranged on the lifting supporting bracket, two pairs of the lifting driving bevel gears are respectively arranged at the driving ends of the two pairs of the lifting driving machines, two pairs of the lifting driving bevel gears are respectively arranged on the two pairs of the lifting screw rods, and two pairs of the lifting transmission bevel gears are respectively engaged with two pairs of the lifting driving bevel gears, two pairs of the auxiliary winches are respectively horizontally arranged on the lifting support bracket, and the other ends of the two pairs of auxiliary winches are connected to the lifting concave plate, and the horizontal extrusion fixing fine-tuning assembly is installed on the inner side of the lifting concave plate.

2. A prefabricated member auxiliary moving support device for building engineering as claimed in claim 1, wherein the telescopic moving fixing structure comprises: the lifting device comprises two pairs of concave lifting limiting blocks, two pairs of lifting support driving machines, two pairs of lifting support driving bevel gears, two pairs of lifting support transmission bevel gears, two pairs of lifting support threaded pipes, two pairs of lifting support threaded rods, two pairs of lifting support concave cylindrical blocks and a telescopic moving assembly;

two pairs of concave lifting limiting blocks are arranged on the inner sides of the concave movable supporting blocks in parallel, two pairs of lifting support driving machines are respectively arranged on the top ends of the two pairs of concave lifting limiting blocks, two pairs of lifting support threaded pipes are respectively inserted into the two pairs of concave lifting limiting blocks through bearings, two pairs of lifting support threaded rods are respectively movably inserted into the inner sides of the two pairs of lifting support threaded pipes, a plurality of lifting support driving bevel gears are respectively arranged at the driving ends of the two pairs of lifting support driving machines, two pairs of lifting support transmission bevel gears are respectively arranged on the outer sides of the two pairs of lifting support threaded pipes, the two pairs of lifting support transmission bevel gears are respectively engaged with the two pairs of lifting support driving bevel gears, and two pairs of lifting support concave cylindrical blocks are respectively arranged at the bottom ends of the two pairs of lifting support threaded rods through bearings, the telescopic moving assembly is arranged on the inner side of the concave moving bearing block.

3. The auxiliary moving and supporting device for prefabricated parts for building engineering as claimed in claim 2, wherein the horizontal extrusion fixing fine-tuning assembly comprises: the horizontal extrusion device comprises a pair of concave horizontal extrusion blocks, a plurality of horizontal extrusion concave wheels, a plurality of horizontal extrusion threaded rods, a plurality of horizontal extrusion threaded pipes, a plurality of horizontal extrusion chain wheels, a pair of horizontal extrusion chains and a pair of horizontal extrusion driving machines;

horizontal extrusion grooves are respectively formed in the side walls of the two sides of the lifting concave plate, a pair of concave horizontal extrusion blocks are respectively movably inserted in the inner sides of the pair of horizontal extrusion grooves, a plurality of horizontal extrusion threaded pipes are respectively inserted in the two sides of the lifting concave plate through bearings, a plurality of horizontal extrusion threaded rods are respectively movably inserted in the inner sides of the plurality of horizontal extrusion threaded pipes, the plurality of horizontal extrusion threaded rods are respectively connected to the pair of concave horizontal extrusion blocks through bearings, a plurality of horizontal extrusion concave wheels are respectively vertically inserted in the inner sides of the pair of concave horizontal extrusion blocks through bearings, a pair of horizontal extrusion drivers are respectively installed on the two sides of the lifting concave plate, a plurality of horizontal extrusion chain wheels are respectively installed on the outer sides of the plurality of horizontal extrusion threaded pipes and the driving ends of the pair of horizontal extrusion drivers, the pair of horizontal extrusion chains is respectively sleeved on the plurality of horizontal extrusion chain wheels, and the movable extrusion part is arranged on the inner sides of the plurality of horizontal extrusion concave wheels.

4. A prefabricated member auxiliary moving support device for building engineering as claimed in claim 3, wherein the telescopic moving assembly comprises: the device comprises a pair of driving shafts, a pair of rotating shafts, two pairs of moving wheels, two pairs of concave circular ring blocks, two pairs of telescopic limiting T-shaped rods, a pair of scissor brackets and two pairs of telescopic spring columns;

the novel telescopic device is characterized in that two pairs of circular arc moving grooves are formed in the concave moving supporting block, locking openings are formed in the inner sides of the two pairs of circular arc moving grooves respectively, one pair of driving shafts are inserted into the concave moving supporting block through bearings, two pairs of concave circular ring blocks are installed on two sides of the rotating shaft respectively, two pairs of concave circular ring blocks are movably inserted into the inner sides of the two pairs of circular arc moving grooves respectively, one pair of scissor type supports are installed on one pair of driving shafts and one pair of rotating shafts respectively, two pairs of telescopic spring columns are installed on one pair of scissor type supports respectively, telescopic grooves are formed in the two pairs of locking openings respectively, two pairs of telescopic limiting T-shaped rods are movably inserted into the inner sides of the two pairs of telescopic grooves respectively, and two pairs of moving wheels are installed on two sides of the driving shafts respectively.

5. The auxiliary moving support device for the prefabricated member for the building engineering as claimed in claim 4, wherein a plurality of the horizontal concave type extrusion blocks are respectively provided with an extrusion rubber pad at the outer side.

6. The auxiliary moving support device for the prefabricated member for the building engineering as claimed in claim 5, wherein a plurality of ball grooves are formed in the two pairs of the circular arc moving grooves, and moving balls are respectively arranged in the plurality of ball grooves.

7. The auxiliary moving and supporting device for the prefabricated parts for building engineering as claimed in claim 1, wherein a rubber pad is arranged at the bottom end of the concave moving and supporting block.

8. The auxiliary moving support device for the prefabricated member for the building engineering as claimed in claim 1, wherein pressure sensors are respectively arranged in the two pairs of concave lifting limiting blocks.

9. The auxiliary moving supporting device for the prefabricated members for the building engineering as claimed in claim 1, wherein a plurality of lifting slideways are arranged on the lifting supporting bracket, a plurality of lifting sliding blocks are arranged on the lifting concave plate, and the plurality of lifting sliding blocks are respectively movably inserted into the plurality of lifting slideways.

10. The auxiliary moving support device for the prefabricated parts for building engineering as claimed in claim 1, wherein an infrared distance meter is arranged outside the concave moving support block.

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