CN113481989B - Anchoring device with lifting combination function for air film building - Google Patents

Abstract

The invention relates to an anchoring device of a gas film building with a lifting combination function, which comprises a power assembly and a spiral head, wherein the interior of the power assembly is connected with a winding assembly, the lower end of the winding assembly is connected with a connecting shaft, the exterior of the connecting shaft is connected with a shell assembly, a wingspan assembly is connected above a locking assembly, the spiral head is positioned at the lower end of the wingspan assembly, the winding assembly comprises a first square rod, a round rod, a winding disc, a fastening bolt and a lead block, the winding disc is arranged outside the first square rod, and the lead blocks are arranged on the left side and the right side of the winding disc. The invention has the beneficial effects that: this anchor with lift combination function air film building can drive two structures through a power supply and carry out work, and is more energy-concerving and environment-protective, and equipment can be convenient for equipment and rope equipment through upgrading the structure, and equipment can expand the stability that the flank increases equipment, and equipment can reset and fix the flank, the taking out of the equipment of being convenient for.

Description

Anchoring device with lifting combination function for air film building

Technical Field

The invention relates to the technical field of energy-saving and environment-friendly air film buildings, in particular to an anchoring device of an air film building with a lifting combination function.

Background

The anchoring means that the reinforcing steel bars are wrapped in concrete, so that the connection between the concrete and the reinforcing steel bars is enhanced, the building is firmer, the purpose is to enable the reinforcing steel bars and the concrete to work together to bear various stresses, the air film building means that a special building film material is used as a shell, a set of intelligent electromechanical equipment is arranged to provide positive pressure of air inside the air film building, a building structure system is used for supporting a building main body, and the air film building needs to be fixed by using an anchoring device when being built.

The one end at the device is directly tied up to fixed rope to current anchor device majority, then deepens the device and install underground thereby carry out work, but will lead to the staff inconvenience to tighten up the rope when the rope is longer to the fixed of equipment to the air film building is not convenient for.

Therefore, the anchoring device for the air film building with the lifting combination function is needed to be designed for solving the problems.

Disclosure of Invention

The invention aims to provide an anchoring device for an air film building with a lifting combination function, which aims to solve the problems that in the background technology, most of anchoring devices are provided, a fixing rope is directly tied at one end of the anchoring device, then the anchoring device is deeply installed underground to work, but when the rope is long, workers cannot conveniently tighten the rope, and therefore the fixing of equipment to the air film building is inconvenient.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides an anchor with lift combination function gas film building, includes power component and spiral head, the internal connection of power component has the rolling subassembly, and the lower extreme of rolling subassembly is connected with the connecting axle, the external connection of connecting axle has the casing subassembly, and the lower extreme of connecting axle is connected with the hasp subassembly, the top of hasp subassembly is connected with span subassembly, and the below of hasp subassembly is provided with back and draws the subassembly, the spiral head is located the lower extreme of span subassembly, the rolling subassembly includes first square bar, round bar, rolling dish, fastening bolt and wire piece, and the upper end of first square bar is connected with the round bar, the outside of first square bar is provided with the rolling dish, and the upper end of rolling dish installs fastening bolt, the left and right sides of rolling dish is provided with the wire piece.

Preferably, the power assembly comprises an upper box body, a motor and a bearing, the motor is mounted at the lower end of the upper box body, and the bearing is embedded in the upper wall and the lower wall of the upper box body.

Preferably, the power assembly further comprises a first gear and a second gear, the right end of the motor is connected with the first gear, and the upper end of the first gear is provided with the second gear.

Preferably, the outer surface of the first gear is meshed with the outer surface of the second gear, and the central axis of the second gear is overlapped with the central axis of the upper box body.

Preferably, the shell assembly includes an outer shell, a connecting pin and a side wing, and the side wing is connected to the left and right sides of the outer shell through the connecting pin.

Preferably, the shell assembly further comprises a sealing film and a protective wing, the protective wing is arranged outside the lower end of the outer shell, and the sealing film is arranged at the upper end of the side wing.

Preferably, the wingspan component comprises a second square rod, a first inclined block and a second inclined block, the first inclined block is arranged on the left side and the right side of the upper end of the second square rod, and the second inclined block is arranged on one side, far away from the second square rod, of the first inclined block.

Preferably, the hasp subassembly includes dwang, kelly and dop, and the left and right sides of dwang is connected with the kelly, and the one end that the dwang was kept away from to the kelly is provided with the dop.

Preferably, the appearance of kelly is L shape, and the kelly is symmetrical about the axis of dwang to be connected for inlaying between kelly and the dop.

Preferably, the pull-back assembly comprises a limit stop and springs, and the springs are arranged on the left side and the right side of the limit stop.

Compared with the prior art, the invention has the beneficial effects that: this equipment can drive two structures through a power supply and carry out work, and is more energy-concerving and environment-protective, and equipment can be convenient for equipment and rope equipment through upgrading the structure, and equipment can expand the stability that the flank increases equipment, and equipment can reset and fix the flank, the taking out of the equipment of being convenient for.

1. The winding disc can be lifted along the first square rod, so that the winding disc can be moved to the round rod, one end of a rope can be conveniently connected to the inside of the winding disc, equipment can be conveniently combined with extension and retraction, one end of the rope can be fixed through the fastening bolt, the winding disc is lowered to the position of the first square rod again after the rope is fixed, the first square rod can be continuously inlaid with the winding disc, and the winding disc can be driven to work when the first square rod rotates.

2. The motor can drive the first square rod to rotate through the first gear and the second gear, so that the first square rod can drive the winding disc to work and wind, and meanwhile, the equipment can drive the spiral head to rotate and drill down, so that one kinetic energy of the equipment drives the two working structures, the kinetic energy generated by the motor can be fully utilized by the equipment, the utilization rate of the energy is increased, the waste of the kinetic energy is reduced, and the equipment has the functions of saving energy and protecting environment.

3. After the device is installed, the screw head can pull the second square rod when the device is pulled, so that the first inclined block descends to prop open the second inclined block, the side wing is unfolded through a rotating structure formed between the connecting pin and the outer shell, the side wing can hook soil on the outer side, resistance generated when the device is pulled outwards is increased, the device is prevented from being pulled out by the stress of a rope, and the stability of the device is increased.

4. According to the invention, when the device needs to be pulled out, the first inclined block can be lifted without ejecting the second inclined block by pressing the device downwards, the side wing can be pulled by the spring to be reset conveniently, so that the side wing does not shield the device from being pulled out, the side wing does not hook soil to generate resistance to facilitate the device to be taken out, meanwhile, the opening of the side wing can be shielded and protected by the sealing film, the soil is prevented from entering the device to block the operation of parts in the device, and meanwhile, the soil contains moisture which can corrode and damage metal parts in the device when entering the device to affect the operation of the device.

5. According to the invention, the connecting shaft can be rotated after the side wings are combined, the rotating rod is driven to rotate, and the clamping rod is clamped in the clamping head, so that the two side wings are fixed, the situation that the spiral head pulls the second square rod when the equipment is pulled out is prevented, the first inclined block descends again to push the second inclined block open, the side wings are stressed to expand, and the resistance applied when the equipment is pulled out is overlarge, so that the equipment is not conveniently pulled out.

Drawings

Fig. 1 is a schematic front view of an anchoring device of a gas film building with a lifting combination function according to the present invention;

FIG. 2 is a schematic sectional view of the housing assembly of the anchoring device of the air film building with the lifting combination function according to the present invention;

FIG. 3 is a schematic cross-sectional view of a power assembly of an anchoring device for a gas film building with a lifting combination function according to the present invention;

fig. 4 is an enlarged structural schematic view of an anchoring device of a gas film building with a lifting combination function in fig. 2;

FIG. 5 is an enlarged schematic structural diagram of the anchoring device of the air film building with the lifting combination function in FIG. 2 at B;

fig. 6 is a schematic perspective view of a housing assembly of an anchoring device of an air film building with lifting combination function according to the present invention.

In the figure: 1. a power assembly; 101. an upper box body; 102. a motor; 103. a first gear; 104. a second gear; 105. a bearing; 2. a winding component; 201. a first square bar; 202. a round bar; 203. a winding disc; 204. fastening a bolt; 205. a lead block; 3. a connecting shaft; 4. a housing assembly; 401. an outer housing; 402. a connecting pin; 403. a side wing; 404. sealing films; 405. a protective wing; 5. a span assembly; 501. a second square bar; 502. a first swash block; 503. a second swash block; 6. a latch assembly; 601. rotating the rod; 602. a clamping rod; 603. clamping a head; 7. a pullback assembly; 701. a limit stop block; 702. a spring; 8. a screw head.

Detailed Description

As shown in fig. 1 to 6, the present invention provides a technical solution: an anchoring device of a gas film building with a lifting combination function comprises a power assembly 1 and a spiral head 8, wherein a winding assembly 2 is connected inside the power assembly 1, the lower end of the winding assembly 2 is connected with a connecting shaft 3, the outer part of the connecting shaft 3 is connected with a shell assembly 4, the lower end of the connecting shaft 3 is connected with a locking assembly 6, a wingspan assembly 5 is connected above the locking assembly 6, a pull-back assembly 7 is arranged below the locking assembly 6, the spiral head 8 is positioned at the lower end of the wingspan assembly 5, the winding assembly 2 comprises a first square rod 201, a round rod 202, a winding disk 203, a fastening bolt 204 and a lead block 205, the upper end of the first square rod 201 is connected with the round rod 202, the outer part of the first square rod 201 is provided with the winding disk 203, the upper end of the winding disk 203 is provided with the fastening bolt 204, and the left side and the right side of the winding disk 203 are provided with the lead blocks 205;

the power assembly 1 can provide power for rotation of the winding assembly 2 and the spiral head 8, the connecting shaft 3 can drive the locking assembly 6 to rotate, the shell assembly 4 can be taken out conveniently, the wingspan assembly 5 can push the shell assembly 4 open, the stability of the equipment is improved, the pull-back assembly 7 can be reset conveniently, the spiral head 8 can facilitate equipment to be inserted into soil, the winding disc 203 can lift along the first square rod 201, the winding disc 203 can be moved to the round rod 202, one end of the rope can be connected to the inside of the winding disc 203 conveniently, the equipment can be combined with the rope in a telescopic mode, one end of the rope can be fixed through the fastening bolt 204, the winding disc 203 can be lowered to the position of the first square rod 201 again after the rope is fixed, the winding disc 203 can be driven to work when the first square rod 201 rotates, and the lead block 205 can facilitate leading-in connection of the rope.

As shown in fig. 3, the power assembly 1 includes an upper case 101, a motor 102 and a bearing 105, the motor 102 is mounted at the lower end of the upper case 101, the bearings 105 are embedded in the upper and lower walls of the upper case 101, the power assembly 1 further includes a first gear 103 and a second gear 104, the first gear 103 is connected to the right end of the motor 102, the second gear 104 is disposed at the upper end of the first gear 103, the outer surface of the first gear 103 is meshed with the outer surface of the second gear 104, and the central axis of the second gear 104 coincides with the central axis of the upper case 101;

the motor 102 can drive the first square rod 201 which forms a rotating structure between the bearing 105 and the upper box 101 to rotate through the first gear 103 and the second gear 104, so that the winding disc 203 works and winds, and meanwhile, the equipment can drive the spiral head 8 to rotate and drill down, so that one kinetic energy of the equipment drives the two working structures, the utilization of the energy is increased, and the equipment has the functions of energy conservation and environmental protection.

As shown in fig. 2 and 6, the shell assembly 4 includes an outer shell 401, a connecting pin 402 and a side wing 403, and the left and right sides of the outer shell 401 are connected with the side wing 403 through the connecting pin 402, the shell assembly 4 further includes a sealing film 404 and a protective wing 405, the protective wing 405 is arranged outside the lower end of the outer shell 401, and the sealing film 404 is arranged at the upper end of the side wing 403;

rely on flank 403 to expand flank 403 through the revolution mechanic that constitutes between connecting pin 402 and the shell body 401, increase the stability that equipment pulled outward, can protect the opening part of flank 403 through sealing membrane 404, prevent inside earth entering equipment, cause the influence to the operation of equipment, protection wing 405 can protect connecting pin 402, prevent that connecting pin 402 from directly crowding into earth in, influence the expansion of flank 403.

As shown in fig. 5, the wingspan assembly 5 includes a second square bar 501, a first oblique block 502 and a second oblique block 503, wherein the first oblique block 502 is disposed on the left and right sides of the upper end of the second square bar 501, and the second oblique block 503 is disposed on the side of the first oblique block 502 away from the second square bar 501;

the second square rod 501 pulls the first sloping block 502, so that the first sloping block 502 descends to prop open the second sloping block 503, and the side wings 403 are unfolded, so that the resistance of pulling the device outwards can be increased, and the stability of the device can be improved.

As shown in fig. 5, the locking assembly 6 includes a rotating rod 601, a locking rod 602 and locking heads 603, wherein the locking rod 602 is connected to the left and right sides of the rotating rod 601, the locking head 603 is disposed at an end of the locking rod 602 away from the rotating rod 601, the locking rod 602 is L-shaped, the locking rod 602 is symmetrical about the central axis of the rotating rod 601, and the locking rod 602 is connected to the locking head 603 in an embedded manner;

the rotating rod 601 can drive the clamping rod 602 to rotate, so that the clamping rod 602 is clamped in the clamping head 603, two side wings 403 are fixed, and the side wings 403 can be unfolded to prevent the equipment from being pulled out.

As shown in fig. 4, the pull-back assembly 7 includes a limit stopper 701 and springs 702, and the springs 702 are disposed on the left and right sides of the limit stopper 701;

the wing 403 is returned by the elastic structure formed between the spring 702 and the stopper 701.

The working principle is as follows: firstly, the winding disc 203 is lifted to the round rod 202, then the rope is wound inside the winding disc 203 after passing through the wire block 205, the rope is pressed tightly through the fastening bolt 204, then the winding disc 203 is lowered to the outside of the first square rod 201 again, then the motor 102 is turned on to drive the second gear 104 to rotate through the first gear 103, so as to drive the first square rod 201 which forms a rotating structure between the bearing 105 and the upper box 101 to rotate, so that the winding disc 203 rotates to wind the rope, meanwhile, the first square rod 201 can drive the connecting shaft 3 to rotate, so that the spiral head 8 also rotates, so that a worker can conveniently insert the equipment into the soil, when the equipment is subjected to the pulling force of the rope after the equipment is installed, the shell assembly 4 can slightly move outwards, so that the first inclined block 502 pushes the second inclined block 503, make flank 403 rely on the revolution mechanic who constitutes between connecting pin 402 and shell body 401 to expand flank 403, increase the resistance that equipment rises, sealing film 404 can seal the mouth that flank 403 expanded, prevent earth from getting into equipment, second square pole 501 can make first sloping block 502 be connected with spiral head 8, thereby can make first sloping block 502 can not remove, be convenient for first sloping block 502 backs down second sloping block 503, the staff only need press down equipment after the equipment finishes using, make first sloping block 502 no longer shelter from second sloping block 503, rely on flank 403 to pass through the elastic construction that constitutes between spring 702 and limit stop 701, make flank 403 reset, then rotate connecting axle 3 and make dwang 601 drive kelly 602 rotate, make kelly 602 block dop 603, thereby can prevent that flank 403 from expanding again when equipment takes out, influence taking out of equipment.

Claims (7)

1. The anchoring device for the air film building with the lifting combination function is characterized by comprising a power assembly (1) and a spiral head (8), wherein a winding assembly (2) is connected inside the power assembly (1), the lower end of the winding assembly (2) is connected with a connecting shaft (3), a shell assembly (4) is connected outside the connecting shaft (3), a locking assembly (6) is connected at the lower end of the connecting shaft (3), a span assembly (5) is connected above the locking assembly (6), a pull-back assembly (7) is arranged below the locking assembly (6), the spiral head (8) is located at the lower end of the span assembly (5), the winding assembly (2) comprises a first square rod (201), a round rod (202), a winding disc (203), a fastening bolt (204) and a wire block (205), the upper end of the first square rod (201) is connected with the round rod (202), the winding disc (201) is arranged outside the first square rod (201), the upper end of the winding disc (203) is provided with the fastening bolt (204), the left and right side inclined rods (203) of the winding disc (203) are provided with a second inclined rod (501), the second inclined rod (501) and the second inclined rod (501) are arranged on the left and right side, one side that second square bar (501) was kept away from in first sloping block (502) is provided with second sloping block (503), hasp subassembly (6) are including dwang (601), kelly (602) and dop (603), and the left and right sides of dwang (601) is connected with kelly (602), and the one end that dwang (601) was kept away from in kelly (602) is provided with dop (603), the outward appearance of kelly (602) appears for L, and kelly (602) is symmetrical about the axis of dwang (601) to be connected for inlaying between kelly (602) and dop (603).

2. The anchoring device for the air film building with the lifting combination function according to claim 1, wherein the power assembly (1) comprises an upper box body (101), a motor (102) and a bearing (105), the motor (102) is installed at the lower end of the upper box body (101), and the bearing (105) is embedded in the upper wall and the lower wall of the upper box body (101).

3. The anchoring device for the air film building with the lifting combination function is characterized in that the power assembly (1) further comprises a first gear (103) and a second gear (104), the first gear (103) is connected to the right end of the motor (102), and the second gear (104) is arranged at the upper end of the first gear (103).

4. The anchoring device for the air film building with the lifting combination function is characterized in that the outer surface of the first gear (103) is meshed with the outer surface of the second gear (104), and the central axis of the second gear (104) is coincident with the central axis of the upper box body (101).

5. The anchoring device for the air film building with the combined lifting and lowering function according to claim 1, wherein the shell assembly (4) comprises an outer shell (401), a connecting pin (402) and a side wing (403), and the side wing (403) is connected to the left side and the right side of the outer shell (401) through the connecting pin (402).

6. The anchoring device for air film buildings with lifting combination functions as claimed in claim 5, wherein the shell assembly (4) further comprises a sealing film (404) and a protective wing (405), the outer part of the lower end of the outer shell (401) is provided with the protective wing (405), and the upper end of the side wing (403) is provided with the sealing film (404).

7. The anchoring device for the air film building with the lifting combination function is characterized in that the pull-back assembly (7) comprises a limit stop (701) and springs (702), and the springs (702) are arranged on the left side and the right side of the limit stop (701).

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