CN216227219U - Air pipe production and processing auxiliary device based on BIM model - Google Patents

Abstract

The utility model discloses an air duct production and processing auxiliary device based on a BIM (building information modeling) model, which comprises a base, wherein an air duct box is fixedly connected to the right side of the top of the base, a feeding shell is arranged on the left side of the air duct box, chains are arranged on the front side and the rear side of the inner part of the feeding shell, a connecting rod is arranged between the two groups of chains, the outer side of the connecting rod is fixedly connected to a conveying plate, the left ends of the inner parts of the two groups of chains are connected to the outer part of a transmission toothed bar, the transmission toothed bar is installed on the front inner wall and the rear inner wall of the top of the feeding shell in a penetrating manner, the right ends of the inner parts of the two groups of chains are connected to the outer part of a driving toothed bar, the driving toothed bar is installed on the front inner wall and the rear inner wall of the right side of the bottom of the feeding shell in a penetrating manner, a driving wheel is fixedly connected to the front end of the driving toothed bar, and a driving wheel is arranged on the left side of the driving wheel. The utility model realizes the adjustment of the positions of the nut and the clamping rod by adjusting the adjusting component and matching the sleeve, the limiting screw, the supporting rod and the positioning hole.

Description

Air pipe production and processing auxiliary device based on BIM model

Technical Field

The utility model relates to the field of air duct production and processing auxiliary devices, in particular to an air duct production and processing auxiliary device based on a BIM (building information modeling) model.

Background

BIM is a datamation tool, and through establishing virtual product three-dimensional model, utilize digital technology, for this model provides complete product information base, improves product information integration degree, because these advantages of BIM, BIM technique is applied to the production and processing trade in a large number, and wherein the tuber pipe production processing auxiliary device based on BIM model is just one of them.

Present tuber pipe production and processing auxiliary device based on BIM model only relies on the transportation piece transportation tuber pipe of installing on the chain in the use, and the application range of equipment has been restricted to distance between the chain, is not convenient for transport to shorter tuber pipe, and stability is on the low side, and the height of clamping chuck can not be adjusted according to the size of tuber pipe to current auxiliary device simultaneously, and application range is comparatively limited.

Therefore, it is necessary to invent an auxiliary device for air duct production and processing based on the BIM model to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an air duct production and processing auxiliary device based on a BIM model, wherein connecting rods and conveying plates are arranged between two groups of chains at equal intervals, and the defects in the technology are overcome through the matching between the connecting rods and the conveying plates and the arrangement of an adjusting assembly.

In order to achieve the above purpose, the utility model provides the following technical scheme: a BIM model-based air duct production and processing auxiliary device comprises a base, wherein a duct box is fixedly connected to the right side of the top of the base, a feeding shell is arranged on the left side of the duct box, chains are arranged on the front side and the rear side of the inner part of the feeding shell, a connecting rod is arranged between the two groups of chains, the outer sides of the connecting rod are fixedly connected to a conveying plate, the left ends of the inner parts of the two groups of chains are connected to the outer part of a transmission toothed bar, the transmission toothed bar is installed on the front inner wall and the rear inner wall of the top of the feeding shell in a penetrating manner, the right ends of the inner parts of the two groups of chains are connected to the outer part of a driving toothed bar in a penetrating manner, the driving toothed bar is installed on the front inner wall and the rear inner wall of the right side of the bottom of the feeding shell in a penetrating manner, a driving wheel is fixedly arranged on the left side of the driving wheel, the driving wheel is fixedly installed on an output shaft of a motor, a processing table is arranged on the left side of the feeding shell, and both sides all are provided with adjusting part around the processing platform, front side adjusting part's rear side outer wall is connected with the nut, and rear side adjusting part's inside through connection has the clamping bar, the top of processing platform is provided with cutting assembly, and the first hydraulic component of cutting assembly's top fixedly connected with, the top fixedly connected with slider of first hydraulic component, and both sides all through connection has the slide bar around the inside of slider, and is two sets of the top of slide bar is provided with the second hydraulic component, and the right-hand member fixed connection of second hydraulic component is in the rear side inner wall of support frame.

Preferably, the connecting rod and the conveying plate are equally spaced between two sets of chains and are welded to each other, the inner side wall of the conveying plate closest to the horizontal distance of the air pipe box is parallel to the bottom surface of the air pipe box, and the bottom surface of the air pipe box is designed to be a 45-degree inclined surface.

Preferably, the transmission toothed bar and the driving toothed bar are in transmission connection with the chain, the driving toothed bar is in key connection with the transmission wheel, the transmission wheel and the driving wheel are in transmission connection with the belt, and the driving wheel is in key connection with an output shaft of the motor.

Preferably, the adjusting assembly is symmetrical about the longitudinal center line of the processing table and comprises a sleeve, a limit screw, a supporting rod and a positioning hole, the side edge of the sleeve is connected with the limit screw, the supporting rod is connected inside the sleeve, and the positioning hole is formed in the side edge of the supporting rod.

Preferably, the locating holes are equidistantly distributed on the outer side wall of the supporting rod, the supporting rod is in sliding connection with the sleeve, the sleeve is in threaded connection with the limiting screw, the diameter of the limiting screw is smaller than that of the locating hole, the supporting rod is in threaded connection with the nut and the clamping rod respectively in the front and rear side adjusting assemblies, the front end of the clamping rod is in a circular truncated cone design, and the transverse center lines of the nut and the clamping rod coincide.

Preferably, the cutting assembly coincides with the longitudinal center line of the processing table, the cutting assembly and the sliding block are respectively and fixedly connected to the top and the bottom of the first hydraulic assembly, the sliding block is in sliding connection with the sliding rod, and the outer wall of the right side of the sliding block is in welded connection with the telescopic rod of the second hydraulic assembly.

In the technical scheme, the utility model provides the following technical effects and advantages:

1. the method comprises the steps that the outer wall diameter and the inner hole diameter of an air pipe are obtained based on a BIM technology, nuts with corresponding sizes are replaced according to the inner hole diameter, adjusting assemblies symmetrically arranged in the front and back of a processing table according to the outer wall diameter, limiting screws on the side edges of a sleeve are unscrewed to be away from positioning holes, supporting rods slide in the sleeve, positions corresponding to the outer wall diameter of the air pipe are adjusted through the positioning holes arranged at equal intervals, the limiting screws are screwed, the supporting rods are limited in position through the matching of the limiting screws and the positioning holes, and the positions of the nuts and clamping rods are adjusted;

2. through equidistant connecting rod and the transport plate of setting up between two sets of chains, strengthened the stability between the chain through the connecting rod, through the cooperation between connecting rod and the transport plate, improve the stability of tuber pipe transportation, and the transport plate welds on the connecting rod, transports through the transport plate, does not receive the restriction of tuber pipe length, improve equipment's practicality.

Drawings

In order to more clearly illustrate the embodiments of the present application or technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to the drawings.

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic perspective view of a loading assembly according to the present invention;

FIG. 3 is a schematic perspective view of the cutting assembly of the present invention;

fig. 4 is a schematic perspective view of an adjustment assembly of the present invention.

Description of reference numerals:

1. a base; 2. an air duct box; 3. a feeding housing; 4. a chain; 5. a connecting rod; 6. a transport plate; 7. a drive rack; 8. a drive rack; 9. a driving wheel; 10. a drive wheel; 11. a belt; 12. a motor; 13. a processing table; 14. an adjustment assembly; 141. a sleeve; 142. a limit screw; 143. a support bar; 144. positioning holes; 15. a nut; 16. a clamping bar; 17. a cutting assembly; 18. a first hydraulic assembly; 19. a slider; 20. a slide bar; 21. a second hydraulic assembly; 22. a support frame.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

The utility model provides an air duct production and processing auxiliary device based on a BIM model, which comprises a base 1, wherein the right side of the top of the base 1 is fixedly connected with an air duct box 2, the left side of the air duct box 2 is provided with a feeding shell 3, the front side and the rear side of the inner part of the feeding shell 3 are respectively provided with a chain 4, a connecting rod 5 is arranged between the two groups of chains 4, the outer side of the connecting rod 5 is fixedly connected with a conveying plate 6, the left ends of the inner parts of the two groups of chains 4 are respectively connected with the outer part of a transmission toothed bar 7, the transmission toothed bar 7 is arranged on the front inner wall and the rear inner wall of the top of the feeding shell 3 in a penetrating way, the right ends of the inner parts of the two groups of chains 4 are respectively connected with the outer part of a driving toothed bar 8, the driving toothed bar 8 is arranged on the front inner wall and the rear inner wall of the right side of the bottom of the feeding shell 3 in a penetrating way, the front end of the driving toothed bar 8 is fixedly connected with a transmission wheel 9, the left side of the transmission wheel 9 is provided with a driving wheel 10, and drive wheel 10 fixed mounting is in the output shaft of motor 12, the left side of pay-off casing 3 is provided with processing platform 13, and both sides all are provided with adjusting part 14 around processing platform 13, the rear side outer wall of front side adjusting part 14 is connected with nut 15, and the inside through connection of rear side adjusting part 14 has clamping bar 16, the top of processing platform 13 is provided with cutting assembly 17, and the top fixedly connected with first hydraulic component 18 of cutting assembly 17, the top fixedly connected with slider 19 of first hydraulic component 18, and the front and back both sides of the inside of slider 19 all through connection have slide bar 20, and two sets of the top of slide bar 20 is provided with second hydraulic component 21, and the right-hand member fixed connection of second hydraulic component 21 is in the rear side inner wall of support frame 22.

Further, in the above technical scheme, the connecting rods 5 and the conveying plates 6 are equally spaced between the two sets of chains 4, and the chains 4 and the connecting rods 5 are welded, the inner side wall of the conveying plate 6 closest to the horizontal distance of the air duct box 2 is parallel to the bottom surface of the air duct box 2, and the bottom surface of the air duct box 2 is designed to be 45 ° inclined surface, when the driving wheel 9 drives the transmission rack bar 7 to rotate through the chains 4, the chains 4 drive the connecting rods 5 and the conveying plates 6 to rotate, because the inner side wall of the conveying plate 6 closest to the horizontal distance of the air duct box 2 is parallel to the bottom surface of the air duct box 2, the bottom surface of the air duct box 2 is designed to be 45 ° inclined surface, the air duct in the air duct box 2 is rolled onto the conveying plate 6, and automatic feeding of the air duct is realized through the rotation of the chains 4.

Further, in the above technical solution, the transmission rack bar 7 and the driving rack bar 8 are both in transmission connection with the chain 4, and the driving rack bar 8 is in key connection with the transmission wheel 9, the transmission wheel 9 and the driving wheel 10 are both in transmission connection with the belt 11, and the driving wheel 10 is in key connection with the output shaft of the motor 12, when the equipment is processed, the motor 12 is powered on to rotate to drive the driving wheel 10 to rotate, the driving wheel 10 drives the transmission wheel 9 to rotate through the belt 11, and the transmission wheel 9 drives the transmission rack bar 7 to rotate through the chain 4.

Further, in the above technical solution, the adjusting assembly 14 is symmetrical about the longitudinal center line of the processing table 13, and the adjusting assembly 14 includes a sleeve 141, a limit screw 142, a support rod 143, and a positioning hole 144, the limit screw 142 is connected to a side edge of the sleeve 141, the support rod 143 is connected to the inside of the sleeve 141, and the positioning hole 144 is opened on a side edge of the support rod 143.

Further, in the above technical solution, the positioning holes 144 are equidistantly distributed on the outer side wall of the supporting rod 143, the supporting rod 143 is slidably connected with the sleeve 141, the sleeve 141 is in threaded connection with the limiting screw 142, the diameter of the limiting screw 142 is smaller than that of the positioning hole 144, the supporting rods 143 of the front and rear side adjusting assemblies 14 are respectively in threaded connection with the nut 15 and the clamping rod 16, the front end of the clamping rod 16 is in a circular truncated cone design, and the transverse center lines of the nut 15 and the clamping rod 16 are overlapped, the outer wall diameter and the inner hole diameter of the air duct are obtained by the BIM technique before processing, the nut 15 with corresponding size is replaced according to the inner hole, the adjusting assemblies 14 symmetrically arranged in front and rear of the processing table 13 are adjusted according to the outer wall diameter, the limiting screw 142 on the side of the sleeve 141 is unscrewed to make the limiting screw 142 far away from the positioning hole 144, the supporting rod 143 slides in the sleeve 141, the position corresponding to the diameter of the outer wall of the air pipe is adjusted through the positioning holes 144 arranged at equal intervals, the limiting screw 142 is screwed, and the position of the supporting rod 143 is limited through the matching of the limiting screw 142 and the positioning holes 144, so that the positions of the nut 15 and the clamping rod 16 are adjusted.

Further, in the above technical solution, the cutting assembly 17 coincides with the longitudinal center line of the processing table 13, and the cutting assembly 17 and the slider 19 are respectively and fixedly connected to the top and the bottom of the first hydraulic assembly 18, the slider 19 is in sliding connection with the slide bar 20, and the outer wall of the right side of the slider 19 is in welded connection with the telescopic rod of the second hydraulic assembly 21, when the air duct length obtained according to the BIM is processed, the telescopic rod of the second hydraulic assembly 21 is controlled to extend, the slider 19 is pushed to slide to the corresponding position on the second hydraulic assembly 21, the telescopic rod of the first hydraulic assembly 18 is controlled to extend, and the telescopic rod of the first hydraulic assembly 18 drives the cutting assembly 17 to fall down, so as to cut and process the air duct.

This practical theory of operation:

referring to the attached drawings 1-4 of the specification, based on the BIM technology, the diameter of the outer wall and the diameter of the inner hole of the air pipe are obtained, the nut 15 with the corresponding size is directly replaced according to the inner hole, the adjusting components 14 symmetrically arranged in front and back of the processing table 13 are adjusted according to the diameter of the outer wall, the limiting screw 142 on the side of the sleeve 141 is loosened to be away from the positioning hole 144, the supporting rod 143 is slid in the sleeve 141, the position corresponding to the diameter of the outer wall of the air pipe is adjusted through the positioning holes 144 arranged at equal intervals, the limiting screw 142 is screwed, and the position of the supporting rod 143 is limited through the matching of the limiting screw 142 and the positioning hole 144, so that the adjustment of the positions of the nut 15 and the clamping rod 16 is realized;

when equipment is machined, a motor 12 is electrified and rotates to drive a driving wheel 10 to rotate, the driving wheel 10 drives a driving wheel 9 to rotate through a belt 11, the driving wheel 9 drives a transmission toothed bar 7 to rotate through a chain 4, meanwhile, the chain 4 drives a connecting rod 5 and a conveying plate 6 to rotate, because the inner side wall of the conveying plate 6 closest to the horizontal distance of an air pipe box 2 is parallel to the bottom surface of the inside of the air pipe box 2, the bottom surface of the inside of the air pipe box 2 is in a 45-degree inclined plane design, an air pipe in the air pipe box 2 is rolled onto the conveying plate 6, and automatic feeding of the air pipe is realized through rotation of the chain 4;

when the air pipe falls into the processing table 13 through the highest position, the front end of the clamping rod 16 is tightly attached to the air pipe by rotating the clamping rod 16, and the air pipe is pushed to be sleeved outside the nut 15, so that the position of the air pipe is limited;

according to the tuber pipe length that BIM reachd, through the telescopic link extension of control second hydraulic component 21, promote slider 19 and slide to corresponding position on second hydraulic component 21, the telescopic link extension of control first hydraulic component 18, the telescopic link area cutting assembly 17 whereabouts of first hydraulic component 18, cuts the processing to the tuber pipe.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the utility model.

Claims (6)

1. The utility model provides an tuber pipe production and processing auxiliary device based on BIM model, includes base (1), its characterized in that: the right side of the top of the base (1) is fixedly connected with an air duct box (2), the left side of the air duct box (2) is provided with a feeding shell (3), chains (4) are arranged on the front side and the rear side of the inner part of the feeding shell (3), a connecting rod (5) is arranged between the two groups of chains (4), the outer side of the connecting rod (5) is fixedly connected with a conveying plate (6), the left ends of the inner parts of the two groups of chains (4) are connected with the outer part of a transmission toothed bar (7), the transmission toothed bar (7) is installed on the front inner wall and the rear inner wall of the top of the feeding shell (3) in a penetrating manner, the right ends of the inner parts of the two groups of chains (4) are connected with the outer part of a driving toothed bar (8), the driving toothed bar (8) is installed on the front inner wall and the rear inner wall of the right side of the bottom of the feeding shell (3) in a penetrating manner, a driving wheel (9) is fixedly connected with the front end of the driving toothed bar (8), and a driving wheel (10) is arranged on the left side of the driving wheel (9), and the driving wheel (10) is fixedly arranged on the output shaft of the motor (12), the left side of the feeding shell (3) is provided with a processing table (13), and the front side and the rear side of the processing table (13) are both provided with adjusting components (14), the outer wall of the rear side of the front side adjusting component (14) is connected with a nut (15), a clamping rod (16) is connected in the rear adjusting component (14) in a penetrating way, a cutting component (17) is arranged above the processing table (13), and the top of the cutting component (17) is fixedly connected with a first hydraulic component (18), the top of the first hydraulic component (18) is fixedly connected with a sliding block (19), sliding rods (20) are respectively connected with the front side and the rear side of the interior of the sliding block (19) in a penetrating way, a second hydraulic component (21) is arranged above the two groups of sliding rods (20), and the right end of the second hydraulic component (21) is fixedly connected with the inner wall of the rear side of the support frame (22).

2. The BIM model-based air duct production and processing auxiliary device according to claim 1, wherein: connecting rod (5) and transport plate (6) equal interval distribution are between two sets of chains (4), and are welded connection between chain (4) and connecting rod (5), keep away from the inboard lateral wall of transport plate (6) that wind pipe case (2) horizontal distance is nearest is parallel to each other with the inside bottom surface of wind pipe case (2), and the inside bottom surface of wind pipe case (2) is 45 inclined plane designs.

3. The BIM model-based air duct production and processing auxiliary device according to claim 1, wherein: the transmission toothed bar (7) and the driving toothed bar (8) are in transmission connection with the chain (4), the driving toothed bar (8) is in key connection with the driving wheel (9), the driving wheel (9) and the driving wheel (10) are in transmission connection with the belt (11), and the driving wheel (10) is in key connection with an output shaft of the motor (12).

4. The BIM model-based air duct production and processing auxiliary device according to claim 1, wherein: the adjusting component (14) is symmetrical about the longitudinal center line of the processing table (13), the adjusting component (14) comprises a sleeve (141), a limiting screw (142), a supporting rod (143) and a positioning hole (144), the side edge of the sleeve (141) is connected with the limiting screw (142), the supporting rod (143) is connected inside the sleeve (141), and the positioning hole (144) is formed in the side edge of the supporting rod (143).

5. The BIM model-based air duct production and processing auxiliary device according to claim 4, wherein: the utility model discloses a supporting rod, including locating hole (144), bracing piece (141), sleeve (141), locating hole (144) equidistant distribution in the outside lateral wall of bracing piece (143), and be sliding connection between bracing piece (143) and the sleeve (141), be threaded connection between sleeve (141) and stop screw (142), and the diameter of stop screw (142) is less than the diameter of locating hole (144), bracing piece (143) are respectively with nut (15) and clamping bar (16) threaded connection in front and back both sides adjusting part (14), and the front end of clamping bar (16) is the design of round platform, and the horizontal central line coincidence of nut (15) and clamping bar (16).

6. The BIM model-based air duct production and processing auxiliary device according to claim 1, wherein: the cutting assembly (17) is overlapped with the longitudinal center line of the processing table (13), the cutting assembly (17) and the sliding block (19) are respectively and fixedly connected to the top and the bottom of the first hydraulic assembly (18), the sliding block (19) is in sliding connection with the sliding rod (20), and the outer wall of the right side of the sliding block (19) is in welded connection with the telescopic rod of the second hydraulic assembly (21).

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