CN112589714A

CN112589714A - Pipeline interfacing apparatus for building

Info

Publication number: CN112589714A
Application number: CN202011525646.3A
Authority: CN
Inventors: 李紫怡
Original assignee: Individual
Current assignee: Shangan Industrial Jiangsu Co ltd
Priority date: 2020-12-22
Filing date: 2020-12-22
Publication date: 2021-04-02
Anticipated expiration: 2040-12-22
Also published as: CN112589714B

Abstract

The invention discloses a pipeline butting device for buildings, which comprises a lifting device, a rotating device, a butting device and a placing platform, wherein the lifting device, the rotating device, the butting device and the placing platform are installed on a rack, an internal mechanical group on the placing platform operates to drive a placing plate to translate, the internal mechanical group in the lifting device operates to drive the placing platform to carry out lifting operation, after the placing platform approaches a pipeline to be butted, the pipeline is connected with a lifting shaft on the placing platform, after the pipeline is connected, the internal mechanical group in the placing platform operates to drive the placing plate to move back to drag the pipeline, after the pipeline is stable, the rotating lifting device and the internal mechanical group in the rotating device operate to drive the pipeline to move to a butting station, and the internal mechanical group in the butting device operates.

Description

Pipeline interfacing apparatus for building

Technical Field

The invention relates to the field of pipeline butt joint, in particular to a pipeline butt joint device for a building.

Background

In many construction fields, the butt joint process of building pipeline and its complicacy, and the butt joint operation of large-scale pipeline is more wasted time and energy, and safety can not be ensured during the butt joint construction, in order to solve this kind of problem, application number CN201821854716.8 discloses a pipeline butt joint device for building, but the device simple structure just can not carry out the automatic movement butt joint to the pipeline.

Disclosure of Invention

To above-mentioned technical problem a pipeline interfacing apparatus for building, including elevating gear, rotary device, interfacing apparatus and place the platform.

The lifting device comprises a rack. The rotating device comprises a rotating transmission bin and a lower driven shaft. The butt joint device comprises a connecting plate, a butt joint transmission bin and a driven straight gear. The placing platform comprises a driven rack, a translation rack and an asynchronous motor fixing plate.

Rack and lift transmission storehouse form sliding fit, rack and rotatory transmission storehouse carry out fixed connection, the downside driven shaft rotate and install in the inboard below shaft hole in rotatory transmission storehouse, the connecting plate rotate and install on the downside driven shaft, butt joint transmission storehouse fixed mounting at the lower surface of connecting plate, driven straight-tooth gear rotate and install the one end at driven worm, driven rack and butt joint transmission storehouse form sliding fit, driven rack and driven straight-tooth gear form gear engagement, translation rack slidable mounting on the connecting plate, translation rack and pipeline place the board and form sliding fit, asynchronous machine fixed plate fixed mounting on the connecting plate.

The lifting device also comprises a fixed beam, a lifting transmission bin, a motor fixing plate, a motor, a driving bevel gear, a lower driven shaft, a lower upper driven bevel gear, a lower driven spur gear, an intermediate driven shaft, an intermediate driven spur gear, an upper driven shaft, an upper driven spur gear, a worm, a supporting plate, a turbine driven shaft, a turbine, a driven bevel gear, a left driven shaft, a left driven bevel gear and a left driven spur gear, wherein the lifting transmission bin is fixedly arranged on the lower surface of the fixed beam, the motor fixing plate is fixedly arranged on the lifting transmission bin, the motor is fixedly arranged on the motor fixing plate, the driving bevel gear is rotatably arranged on the motor, the lower driven shaft is rotatably arranged in a lower shaft hole of the lifting transmission bin, the lower upper driven bevel gear is rotatably arranged on the lower driven shaft, and the lower driven bevel gear and the driving bevel gear form gear meshing, the lower driven spur gear is rotatably arranged on the lower driven shaft and is positioned below the lower driven helical gear, the middle driven shaft is rotatably arranged in a middle shaft hole of the lifting transmission bin, the middle driven spur gear is rotatably arranged on the middle driven shaft, the upper driven shaft is rotatably arranged in an upper shaft hole of the lifting transmission bin, the upper driven spur gear is rotatably arranged on the upper driven shaft, the upper driven spur gear and the middle driven spur gear form gear engagement, the worm is rotatably arranged on the lifting transmission bin, the worm is fixedly connected with the upper driven shaft, the supporting plate is fixedly arranged on the upper surface of the lower side of the lifting transmission bin, the turbine driven shaft is rotatably arranged on the supporting plate, the turbine is rotatably arranged on the turbine driven shaft, the turbine is in gear engagement with the worm, and the driven helical gear is rotatably arranged on the turbine driven shaft, the left driven shaft is rotatably installed in a left shaft hole of the lifting transmission bin, the left driven helical gear is rotatably installed on the left driven shaft, the left driven helical gear and the driven helical gear form gear engagement, and the left driven straight gear is rotatably installed on the left driven shaft and is located on the rear side of the left driven helical gear.

The rotating device also comprises a servo motor fixing plate, a servo motor, a right belt pulley, a left belt pulley driven shaft, a left belt pulley, a belt, a middle lower driven straight gear, a right driven shaft, a right upper driven straight gear, a right lower driven helical gear, a right lower driven shaft, a left driven helical gear, a right driven helical gear and a lower side driven helical gear, wherein the servo motor fixing plate is fixedly arranged at the inner side of the rotary transmission bin, the servo motor is fixedly arranged on the servo motor fixing plate, the right belt pulley is rotatably arranged on the servo motor, the left belt pulley driven shaft is rotatably arranged in a left shaft hole of the rotary transmission bin, the left belt pulley is rotatably arranged on the left belt pulley driven shaft, the middle lower driven straight gear is rotatably arranged on the left belt pulley driven shaft and is positioned below the left belt pulley, the right driven shaft is rotatably arranged in a right shaft hole of the rotary transmission, the right side on driven straight-toothed gear rotate and install on right driven shaft, the right side on driven straight-toothed gear and middle driven straight-toothed gear form gear engagement down, the right side under driven helical gear rotate install on right driven shaft lie in the right side on driven straight-toothed gear's below, the right side under driven shaft rotate install in the side shaft hole in rotatory transmission storehouse, the driven helical gear of left side rotate install under the right side on the driven shaft, the driven helical gear of left side under and right side form gear engagement, the driven helical gear of right side rotate install under the right side on the driven shaft lie in the right side of the driven helical gear of left side, the driven helical gear of downside rotate and install on the downside driven shaft, the driven helical gear of downside and the driven helical gear of right side form gear engagement.

The butt joint device also comprises a step motor fixing plate, a step motor, a left driving helical gear, an upper driven shaft, a middle upper driven helical gear, a driven turbine and a driven worm, the stepping motor fixing plate is fixedly arranged on the upper surface of the inner side of the butt joint transmission bin, the stepping motor is fixedly arranged on the stepping motor fixing plate, the left driving bevel gear is rotationally arranged on the stepping motor, the upper driven shaft is rotationally arranged on the butt joint transmission bin, the middle upper driven helical gear is rotatably arranged on the upper driven shaft, the middle upper driven helical gear and the left driving helical gear form gear engagement, the driven turbine is rotatably arranged on the upper driven shaft and is positioned below the middle upper driven bevel gear, the driven worm is rotatably arranged on the butt joint transmission bin, and the driven worm and the driven turbine form gear engagement.

The place the platform still include connecting block, hoist and mount axle, spring connecting axle, pipeline and place board, asynchronous machine and lower driven straight-teeth gear, connecting block fixed mounting at the tip of driven rack, hoist and mount axle and connecting block carry out fixed connection, connecting block, hoist and mount axle, spring connecting axle have two sets of left and right sides of installing respectively at driven rack, the pipeline place board both sides shaft hole and pass two spring connecting axles respectively, asynchronous machine fixed mounting on the asynchronous machine fixed plate, lower driven straight-teeth gear rotate and install on asynchronous machine, lower driven straight-teeth gear and translation rack form gear engagement.

Further, the middle driven spur gear and the lower driven spur gear form gear meshing.

Furthermore, the belt is in belt transmission fit with the left belt pulley and the right belt pulley.

Furthermore, the spring is matched with the hoisting shaft and the spring connecting shaft through the spring.

Compared with the prior art, the invention has the beneficial effects that: (1) the invention can adapt to various specifications and carry out sorting operation on the color particle mother. (2) The invention can convey the color particle mother granules with different specifications to the storage box, and can improve the efficiency. (3) The invention can automatically replace the full storage tank, thereby greatly saving the cost.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic structural diagram of the lifting device of the present invention.

Fig. 3 is a schematic view of the internal assembly structure of the lifting device of the present invention.

FIG. 4 is a schematic view of the internal structure of the rotating device of the present invention.

Fig. 5 is a schematic view of the internal assembly of the docking device of the present invention.

Fig. 6 is a schematic structural diagram of the docking device of the present invention.

Fig. 7 is a schematic view of the internal structure of the placement platform of the present invention.

Reference numerals: 1-a lifting device; 2-a rotating device; 3-a docking device; 4-placing a platform; 101-a fixed beam; 102-lifting transmission cabin; 103-motor fixing plate; 104-a motor; 105-a driving bevel gear; 106-lower driven shaft; 107-driven bevel gear on lower side; 108-lower driven spur gear; 109-intermediate driven shaft; 110-intermediate driven spur gear; 111-upper driven shaft; 112-upper driven spur gear; 113-a worm; 114-a support plate; 115-a turbine driven shaft; 116-a turbine; 117-driven bevel gear; 118-left driven shaft; 119-left driven bevel gear; 120-left driven spur gear; 121-rack bar; 201-rotating the transmission bin; 202-servo motor fixing plate; 203-a servo motor; 204-right belt pulley; 205-left pulley driven shaft; 206-left pulley; 207-a belt; 208-middle lower driven spur gear; 209-right driven shaft; 210-driven spur gear on right side; 211-right lower driven bevel gear; 212-right lower driven shaft; 213-left driven bevel gear; 214-right driven bevel gear; 215-lower driven shaft; 216-lower driven bevel gear; 301-connecting plate; 302-butting the transmission bin; 303-step motor fixing plate; 304-a stepper motor; 305-left driving bevel gear; 306-upper driven shaft; 307-middle upper driven bevel gear; 308-a driven turbine; 309-driven worm; 310-a driven spur gear; 401-driven rack; 402-connecting block; 403-hoisting shaft; 404-a spring; 405-a spring connection shaft; 406-a pipe placement plate; 407-a translation rack; 408-an asynchronous motor fixing plate; 409-asynchronous machine; 410-lower driven spur gear.

Detailed Description

The present invention will be further described with reference to specific examples, which are illustrative of the invention and are not to be construed as limiting the invention.

As shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6 and fig. 7, the docking device for a pipeline for construction includes a lifting device 1, a rotating device 2, a docking device 3 and a placing platform 4.

The lifting device 1 comprises a rack 121; the rotating device 2 comprises a rotating transmission bin 201 and a lower driven shaft 215; the butt joint device 3 comprises a connecting plate 301, a butt joint transmission bin 302 and a driven spur gear 310; the placing platform 4 comprises a driven rack 401, a translation rack 407 and an asynchronous motor fixing plate 408.

Rack 121 and lift transmission storehouse 102 form sliding fit, rack 121 and rotatory transmission storehouse 201 carry out fixed connection, downside driven shaft 215 rotates and installs in the inboard below shaft hole of rotatory transmission storehouse 201, connecting plate 301 rotates and installs on downside driven shaft 215, butt joint transmission storehouse 302 fixed mounting is at the lower surface of connecting plate 301, driven spur gear 310 rotates and installs the one end at driven worm 309, driven rack 401 and butt joint transmission storehouse 302 form sliding fit, driven rack 401 and driven spur gear 310 form gear engagement, translation rack 407 slidable mounting is on connecting plate 301, translation rack 407 and pipeline place board 406 form sliding fit, asynchronous machine fixed plate 408 fixed mounting is on connecting plate 301.

The lifting device 1 further comprises a fixed beam 101, a lifting transmission bin 102, a motor fixing plate 103, a motor 104, a driving bevel gear 105, a lower driven shaft 106, a lower upper driven bevel gear 107, a lower driven spur gear 108, an intermediate driven shaft 109, an intermediate driven spur gear 110, an upper driven shaft 111, an upper driven spur gear 112, a worm 113, a supporting plate 114, a turbine driven shaft 115, a turbine 116, a driven bevel gear 117, a left driven shaft 118, a left driven bevel gear 119 and a left driven spur gear 120, wherein the lifting transmission bin 102 is fixedly arranged on the lower surface of the fixed beam 101, the motor fixing plate 103 is fixedly arranged on the lifting transmission bin 102, the motor 104 is fixedly arranged on the motor fixing plate 103, the driving bevel gear 105 is rotatably arranged on the motor 104, the lower driven shaft 106 is rotatably arranged in a lower shaft hole of the lifting transmission bin 102, the lower upper driven bevel gear 107, an upper driven bevel gear 107 on the lower side is in gear engagement with the driving bevel gear 105, a lower driven spur gear 108 is rotatably mounted on a lower driven shaft 106 below the upper driven bevel gear 107 on the lower side, a motor 104 is a power source, when the motor 104 rotates, the upper driven bevel gear 107 on the lower side is driven to synchronously rotate with a lower driven spur gear 108 synchronously connected with the lower driven bevel gear, an intermediate driven shaft 109 is rotatably mounted in an intermediate shaft hole of the lifting transmission bin 102, an intermediate driven spur gear 110 is rotatably mounted on the intermediate driven shaft 109, when the lower driven spur gear 108 rotates, the intermediate driven spur gear 110 is driven to rotate, an upper driven shaft 111 is rotatably mounted in an upper shaft hole of the lifting transmission bin 102, an upper driven spur gear 112 is rotatably mounted on the upper driven shaft 111, the upper driven spur gear 112 and the intermediate driven spur gear 110 form gear engagement, a worm 113 is rotatably mounted on the lifting transmission bin 102, and the worm 113 is fixedly, when the middle driven spur gear 110 rotates, the upper driven spur gear 112 and the worm 113 connected with the upper driven spur gear are driven to synchronously rotate, the supporting plate 114 is fixedly installed on the upper surface of the lower side of the lifting transmission bin 102, the turbine driven shaft 115 is rotatably installed on the supporting plate 114, the turbine 116 is rotatably installed on the turbine driven shaft 115, the turbine 116 forms gear engagement with the worm 113, the driven helical gear 117 is rotatably installed on the turbine driven shaft 115, the turbine 116 and the driven helical gear 117 synchronously connected with the turbine are driven to synchronously rotate when the worm 113 rotates, the left driven shaft 118 is rotatably installed in a left shaft hole of the lifting transmission bin 102, the left driven helical gear 119 is rotatably installed on the left driven shaft 118, the left driven helical gear 119 forms gear engagement with the driven helical gear 117, the left driven spur gear 120 is rotatably installed on the left driven shaft 118 at the rear side of the left driven helical gear 119, and the left driven helical gear 119 and the left driven helical gear 120, the rack gear 121 is driven to move when the left driven spur gear 120 rotates.

The rotating device 2 further comprises a servo motor fixing plate 202, a servo motor 203, a right belt pulley 204, a left belt pulley driven shaft 205, a left belt pulley 206, a belt 207, a middle lower driven spur gear 208, a right driven shaft 209, a right upper driven spur gear 210, a right lower driven helical gear 211, a right lower driven shaft 212, a left driven helical gear 213, a right driven helical gear 214 and a lower driven helical gear 216, wherein the servo motor fixing plate 202 is fixedly arranged at the inner side of the rotating transmission bin 201, the servo motor 203 is fixedly arranged on the servo motor fixing plate 202, the right belt pulley 204 is rotatably arranged on the servo motor 203, the servo motor 203 is a power source, the right belt pulley 204 is driven to rotate when the servo motor 203 rotates, the left belt pulley 205 is rotatably arranged in a left shaft hole of the rotating transmission bin 201, the left belt pulley 206 is rotatably arranged on the left belt pulley driven shaft 205, the middle lower driven spur gear 208 is rotatably arranged on the, when the right belt pulley 204 rotates, the belt 207 drives the left belt pulley 206 and the middle lower driven spur gear 208 synchronously connected with the left belt pulley to synchronously rotate, the right driven shaft 209 is rotatably installed in a right shaft hole of the rotary transmission bin 201, the right upper driven spur gear 210 is rotatably installed on the right driven shaft 209, the right upper driven spur gear 210 and the middle lower driven spur gear 208 form gear engagement, the right lower driven helical gear 211 is rotatably installed on the right driven shaft 209 below the right upper driven spur gear 210, the middle lower driven spur gear 208 drives the right upper driven spur gear 210 and the right lower driven helical gear 211 synchronously connected with the right upper driven spur gear to synchronously rotate, the right lower driven shaft 212 is rotatably installed in a side shaft hole of the rotary transmission bin 201, the left driven helical gear 213 is rotatably installed on the right lower driven shaft 212, and the left driven helical gear 213 and the right lower driven helical gear 211 form gear engagement, the right driven bevel gear 214 is rotatably mounted on the right lower driven shaft 212 at the right side of the left driven bevel gear 213, and drives the left driven bevel gear 213 and the right driven bevel gear 214 synchronously connected therewith to rotate when the right lower driven bevel gear 211 rotates, the lower driven bevel gear 216 is rotatably mounted on the lower driven shaft 215, and the lower driven bevel gear 216 and the right driven bevel gear 214 form gear engagement.

The docking device 3 further comprises a stepping motor fixing plate 303, a stepping motor 304, a left driving bevel gear 305, an upper driven shaft 306, an intermediate upper driven bevel gear 307, a driven worm gear 308 and a driven worm 309, wherein the stepping motor fixing plate 303 is fixedly arranged on the upper surface of the inner side of the docking transmission bin 302, the stepping motor 304 is fixedly arranged on the stepping motor fixing plate 303, the left driving bevel gear 305 is rotatably arranged on the stepping motor 304, the stepping motor fixing plate 304 is a power source and drives the left driving bevel gear 305 to transmit when the stepping motor fixing plate 304 rotates, the upper driven shaft 306 is rotatably arranged on the docking transmission bin 302, the intermediate upper driven bevel gear 307 is rotatably arranged on the upper driven shaft 306, the intermediate upper driven bevel gear 307 is in gear engagement with the left driving bevel gear 305, and the driven worm gear 308 is rotatably arranged on the upper driven shaft 306 and is, when the left driving bevel gear 305 rotates, the middle upper driven bevel gear 307 and a driven worm gear 308 synchronously connected with the middle upper driven bevel gear are driven to rotate, a driven worm 309 is rotatably installed on the butt joint transmission bin 302, the driven worm 309 and the driven worm gear 308 form gear engagement, and when the driven worm gear 308 rotates, the driven worm 309 and a driven spur gear 310 synchronously connected with the driven worm are driven to rotate synchronously.

The placing platform 4 further comprises a connecting block 402, a hoisting shaft 403, a spring 404, a spring connecting shaft 405, a pipeline placing plate 406, an asynchronous motor 409 and a lower driven spur gear 410, the connecting block 402 is fixedly installed at the end of the driven rack 401, when the driven straight gear 310 rotates, the driven rack 401 is driven to move, the hoisting shaft 403 is fixedly connected with the connecting block 402, two groups of the connecting block 402, the hoisting shaft 403, the spring 404 and the spring connecting shaft 405 are respectively arranged at the left side and the right side of the driven rack 401, shaft holes at two sides of the pipeline placing plate 406 respectively penetrate through the two spring connecting shafts 405, the asynchronous motor 409 is fixedly arranged on an asynchronous motor fixing plate 408, the lower driven straight gear 410 is rotatably arranged on the asynchronous motor 409, the asynchronous motor 409 is a power source, when the asynchronous motor 409 rotates, the lower driven spur gear 410 is driven to rotate, the lower driven spur gear 410 and the translation rack 407 form gear engagement, and when the lower driven spur gear 410 rotates, the translation rack 407 is driven to move.

The intermediate driven spur gear 110 is in gear engagement with the lower driven spur gear 108. The belt 207 is in belt driving engagement with the left pulley 206 and the right pulley 204. Spring 404 forms a spring fit with hoist shaft 403 and spring connecting shaft 405.

Claims

1. The utility model provides a pipeline interfacing apparatus for building, includes elevating gear (1), rotary device (2), interfacing apparatus (3) and place platform (4), its characterized in that:

the lifting device (1) comprises a rack (121);

the rotating device (2) comprises a rotating transmission bin (201) and a lower driven shaft (215);

the butt joint device (3) comprises a connecting plate (301), a butt joint transmission bin (302) and a driven spur gear (310);

the placing platform (4) comprises a driven rack (401), a translation rack (407) and an asynchronous motor fixing plate (408);

rack 121 and lift transmission storehouse (102) form sliding fit, rack (121) and rotatory transmission storehouse (201) carry out fixed connection, downside driven shaft (215) rotate and install in the inboard below shaft hole of rotatory transmission storehouse (201), connecting plate (301) rotate and install on downside driven shaft (215), butt joint transmission storehouse (302) fixed mounting at the lower surface of connecting plate (301), driven spur gear (310) rotate and install the one end at driven worm (309), driven rack (401) and butt joint transmission storehouse (302) form sliding fit, driven rack (401) and driven spur gear (310) form gear engagement, translation rack (407) sliding mounting on connecting plate (301), translation rack (407) and pipeline place board (406) and form sliding fit, the asynchronous motor fixing plate (408) is fixedly arranged on the connecting plate (301).

2. The butt joint device for construction pipelines of claim 1, wherein: the lifting device (1) further comprises a fixed beam (101), a lifting transmission bin (102), a motor fixing plate (103), a motor (104), a driving bevel gear (105), a lower driven shaft (106), a lower upper driven bevel gear (107), a lower side driven spur gear (108), an intermediate driven shaft (109), an intermediate driven spur gear (110), an upper driven shaft (111), an upper driven spur gear (112), a worm (113), a supporting plate (114), a turbine driven shaft (115), a turbine (116), a driven bevel gear (117), a left driven shaft (118), a left driven bevel gear (119) and a left driven spur gear (120), wherein the lifting transmission bin (102) is fixedly arranged on the lower surface of the fixed beam (101), the motor fixing plate (103) is fixedly arranged on the lifting transmission bin (102), and the motor (104) is fixedly arranged on the motor fixing plate (103), the driving bevel gear (105) is rotatably installed on the motor (104), the lower driven shaft (106) is rotatably installed in a lower shaft hole of the lifting transmission bin (102), the lower driven bevel gear (107) is rotatably installed on the lower driven shaft (106) on the lower side, the lower driven bevel gear (107) and the driving bevel gear (105) form gear engagement, the lower driven spur gear (108) is rotatably installed on the lower driven shaft (106) below the lower driven bevel gear (107) on the lower side, the middle driven shaft (109) is rotatably installed in a middle shaft hole of the lifting transmission bin (102), the middle driven spur gear (110) is rotatably installed on the middle driven shaft (109), the upper driven shaft (111) is rotatably installed in an upper shaft hole of the lifting transmission bin (102), the upper driven spur gear (112) is rotatably installed on the upper driven shaft (111), go up driven spur gear (112) and middle driven spur gear (110) form gear engagement, worm (113) rotate and install on lift transmission storehouse (102), worm (113) and last driven shaft (111) carry out fixed connection, backup pad (114) fixed mounting at lift transmission storehouse (102) downside upper surface, turbine driven shaft (115) rotate and install on backup pad (114), turbine (116) rotate and install on turbine driven shaft (115), turbine (116) and worm (113) form gear engagement, driven helical gear (117) rotate and install on turbine driven shaft (115), left driven shaft (118) rotate and install in the left side shaft hole of lift transmission storehouse (102), left driven helical gear (119) rotate and install on left driven shaft (118), left driven helical gear (119) and driven helical gear (117) form gear engagement, the left driven straight gear (120) is rotatably arranged on the left driven shaft (118) and is positioned at the rear side of the left driven helical gear (119).

3. The butt joint device for construction pipelines of claim 1, wherein: the rotating device (2) further comprises a servo motor fixing plate (202), a servo motor (203), a right belt pulley (204), a left belt pulley driven shaft (205), a left belt pulley (206), a belt (207), a middle lower driven spur gear (208), a right driven shaft (209), a right upper driven spur gear (210), a right lower driven helical gear (211), a right lower driven shaft (212), a left driven helical gear (213), a right driven helical gear (214) and a lower driven helical gear (216), wherein the servo motor fixing plate (202) is fixedly arranged on the inner side of the rotary transmission bin (201), the servo motor (203) is fixedly arranged on the servo motor fixing plate (202), the right belt pulley (204) is rotatably arranged on the servo motor (203), the left belt pulley driven shaft (205) is rotatably arranged in a left shaft hole of the rotary transmission bin (201), left belt pulley (206) rotate and install on left belt pulley driven shaft (205), middle lower driven spur gear (208) rotate and install the below that is located left belt pulley (206) on left belt pulley driven shaft (205), right driven shaft (209) rotate and install in the right side shaft hole of rotatory transmission storehouse (201), right side on driven spur gear (210) rotate and install on right driven shaft (209), right side on driven spur gear (210) and middle lower driven spur gear (208) form gear engagement, right side under driven helical gear (211) rotate and install the below that is located right side on driven shaft (209) on right driven shaft (210), right side under driven shaft (212) rotate and install in the side shaft hole of rotatory transmission storehouse (201), left side driven helical gear (213) rotate and install under the right side on driven shaft (212), driven helical gear (213) and the driven helical gear (211) form gear engagement under the right side, driven helical gear (214) of right side rotate and install under the right side on driven shaft (212) lie in the right side of driven helical gear (213) of left side, driven helical gear (216) of downside rotate and install on downside driven shaft (215), driven helical gear (216) of downside and driven helical gear (214) form gear engagement.

4. The butt joint device for construction pipelines of claim 1, wherein: butt joint device (3) still include step motor fixed plate (303), step motor (304), left side drive helical gear (305), upside driven shaft (306), middle driven helical gear (307), driven turbine (308) and driven worm (309) of going up, step motor fixed plate (303) fixed mounting at the inboard upper surface of butt joint transmission storehouse (302), step motor (304) fixed mounting on step motor fixed plate (303), left side drive helical gear (305) rotate and install on step motor (304), upside driven shaft (306) rotate and install on butt joint transmission storehouse (302), middle driven helical gear (307) of going up rotate and install on upside driven shaft (306), middle driven helical gear (307) and left side drive helical gear (305) form gear engagement, driven turbine (308) rotate and install on upside driven shaft (306) and lie in the middle driven helical gear (307) of going up driven helical gear (307) And the driven worm (309) is rotatably arranged on the butt joint transmission bin (302), and the driven worm (309) and the driven turbine (308) form gear engagement.

5. The butt joint device for construction pipelines of claim 1, wherein: the placing platform (4) also comprises a connecting block (402), a hoisting shaft (403), a spring (404), a spring connecting shaft (405), a pipeline placing plate (406), an asynchronous motor (409) and a lower driven spur gear (410), the connecting block (402) is fixedly arranged at the end part of the driven rack (401), the hoisting shaft (403) is fixedly connected with the connecting block (402), two groups of connecting blocks (402), hoisting shafts (403), springs (404) and spring connecting shafts (405) are respectively arranged at the left side and the right side of the driven rack (401), two side shaft holes of the pipeline placing plate (406) respectively pass through two spring connecting shafts (405), the asynchronous motor (409) is fixedly arranged on an asynchronous motor fixing plate (408), the lower driven spur gear (410) is rotationally arranged on the asynchronous motor (409), the lower driven straight gear (410) and the translation rack (407) form gear engagement.

6. The butt joint device for construction pipelines of claim 1, wherein: the middle driven spur gear (110) and the lower driven spur gear (108) form gear meshing.

7. The butt joint device for construction pipelines of claim 1, wherein: the belt (207) is in belt transmission fit with the left belt pulley (206) and the right belt pulley (204).

8. The butt joint device for construction pipelines of claim 1, wherein: the spring (404), the hoisting shaft (43) and the spring connecting shaft (405) form spring fit.