CN110029581B

CN110029581B - Cement pouring equipment for bridge construction

Info

Publication number: CN110029581B
Application number: CN201910309792.3A
Authority: CN
Inventors: 孙小燕
Original assignee: Individual
Current assignee: Hubei Tengfa Construction Co ltd; Hubei Zhonglai Technology Service Co ltd
Priority date: 2019-04-17
Filing date: 2019-04-17
Publication date: 2020-10-23
Anticipated expiration: 2039-04-17
Also published as: CN110029581A

Abstract

The invention discloses a cement pouring device for bridge construction, which comprises a shell mechanism, a supporting traction mechanism, a pouring mechanism and a stirring mechanism, wherein the supporting traction mechanism and the pouring mechanism are respectively and fixedly arranged at two sides of the shell mechanism, and the stirring mechanism is fixedly arranged in an inner cavity of the shell mechanism, satisfy the operation of pouring of difference, further improve holistic efficiency of pouring.

Description

Cement pouring equipment for bridge construction

Technical Field

The invention relates to the technical field of bridge construction, in particular to cement pouring equipment for bridge construction.

Background

Need carry out concrete placement to steel bar structure in present bridge construction field, improve bridge steel construction's support toughness, traditional cement pouring equipment has in the use to pour the problem that the injection direction is single and cement polymer mixed particle size is too big, need design a bridge construction to this cement pouring equipment.

Disclosure of Invention

The present invention has been made to solve the above problems, and an object of the present invention is to provide a cement casting apparatus for bridge construction, which solves the problems of a single casting angle and an excessively large cement polymer mixing particle size of the conventional cement casting apparatus.

In order to solve the above problems, the present invention provides a technical solution: the utility model provides a bridge construction is with cement equipment of pouring, includes shell mechanism, support drive mechanism, pours mechanism and rabbling mechanism, shell mechanism both sides fixed mounting respectively has support drive mechanism and pours the mechanism, fixed mounting has the rabbling mechanism in the shell mechanism inner chamber.

Preferably, the shell mechanism comprises a shell, a visual glass, a toggle groove, a feeding hole, wheels, a connecting shaft, a rotating ring and a supporting rod, the two sides of the shell are both provided with hollow grooves, two pieces of visual glass are respectively embedded in the two hollow grooves and are respectively designed to be matched with the specifications of the two hollow grooves, a toggle groove is arranged on one side of the shell through the inner cavity, a feeding port is arranged at the upper end of the shell and is communicated with the inner cavity of the shell, the wheels are arranged below the shell, the two wheels are arranged, the specifications of the two wheels are consistent, the two wheels are mutually and symmetrically distributed around the transverse center line of the lower end surface of the shell, the circle centers of the two wheels at the opposite sides are fixedly connected through a connecting shaft, two rotating rings are rotatably sleeved on the connecting shaft, and the two rotating rings are fixedly connected with the lower end face of the shell through two supporting rods respectively.

Preferably, the supporting and traction mechanism comprises a first connecting piece, a fixing ring, an L-shaped connecting plate, a worm gear shell, a lead screw, a top cap, a supporting plate, a first motor, a second connecting piece, a connecting seat and a screw head, wherein the first connecting piece is fixedly arranged on one side of the shell mechanism, the fixing ring is vertically and fixedly connected to one side of the first connecting piece, the L-shaped connecting plate is vertically and fixedly arranged at the corner of one side of the shell mechanism, the worm gear shell is fixedly arranged on the inner side edge of the L-shaped connecting plate, a worm gear is rotatably arranged in the worm gear shell, the lead screw is in threaded connection with the output end of the worm gear, the top cap is fixedly arranged at the upper top end of the lead screw, the supporting plate is arranged under the L-shaped connecting plate, the lower end of the lead screw penetrates through the L-shaped, the output end of the first motor is fixedly connected with a worm, the worm is meshed with the input end of a worm wheel, one side of the L-shaped connecting plate is fixedly provided with a connecting seat through a second connecting piece, and the end part of the connecting seat is fixedly provided with a threaded head.

Preferably, the pouring mechanism comprises a pouring pump, a material storage port, a butterfly valve, a material outlet, a main material spraying pipe, a first material spraying pipe, a rotating groove, an inner groove, a second motor, an engaging shaft, a second material spraying pipe, a first rotating part, a limiting groove and a second rotating part, the pouring pump is provided with two output ends, the lower end of the pouring pump is fixedly connected with the material storage port, one of the output ends is communicated with the material storage port, the lower end of the material storage port is fixedly connected with the material outlet, the material outlet is communicated with the material storage port, the butterfly valve is arranged at the joint of the material outlet and the material storage port, the main material spraying pipe is arranged on one side of the pouring pump, the first material spraying pipe is communicated with one side of the main material spraying pipe, the rotating groove and the inner groove are arranged in the inner cavity of the first material spraying pipe, the inner groove is communicated with the rotating groove, the, the meshing shaft is connected with the first material spraying pipe in a meshing mode, the other output end of the pouring pump is fixedly communicated with a second material spraying pipe, the end portion of the second material spraying pipe is fixedly connected with a first rotating piece, the first rotating piece and the rotating groove are designed in a matched mode and are arranged correspondingly, through holes are formed in the center positions of two opposite side edges of the first rotating piece in a penetrating mode, a limiting groove is formed in one side of the pouring pump, a second rotating piece is arranged in the limiting groove, and one side of the second rotating piece is fixedly connected with one side of the main material spraying pipe through a connecting rod.

As preferred, be provided with rabbling mechanism in the shell mechanism inner chamber, be provided with the stirring chamber in the rabbling mechanism, the last top surface central point of stirring chamber inner chamber puts fixed mounting has the third motor, third motor output end fixedly connected with driving shaft, the fixed stirring roller that is equipped with that is adorned on the driving shaft, the row material chamber has been seted up to the rabbling mechanism lower extreme, it is equipped with the pumping pipe to arrange the material intracavity, pumping pipe one end and pouring pump input end intercommunication, the regulation chamber has been seted up between stirring chamber and the row material chamber, it is provided with the adjustment disk to adjust the intracavity, the upper and lower terminal surface central point of adjustment disk puts fixed mounting respectively has the regulation pole, the outer arc limit fixedly connected with poker rod of adjustment disk, poker rod one end sets up in stirring the.

Preferably, bearings are fixedly mounted at the center positions of the upper cavity wall and the lower cavity wall of the adjusting cavity, the bottom of the lower cavity of the stirring cavity and the top of the upper cavity of the discharging cavity respectively penetrate through the adjusting cavity and are provided with discharging holes, the discharging holes are divided into two layers, and the two layers of the discharging holes are correspondingly arranged between the holes.

Preferably, a plurality of material through holes are formed between the upper disc surface and the lower disc surface of the adjusting disc in a penetrating mode, and the material through holes are matched with the plurality of blanking holes in the two layers respectively and are arranged in corresponding positions.

Preferably, the adjusting disc is rotatably mounted with the upper and lower chamber walls of the adjusting chamber through two adjusting rods and two bearings.

Preferably, the two outer side arc walls of the material pumping pipe penetrate through the pipe cavity respectively and are provided with material sucking holes, the material sucking holes are divided into two rows, and the material sucking holes in each row are arranged at equal intervals.

The invention has the beneficial effects that: the invention relates to a cement pouring device for bridge construction, which has the characteristics of various spraying directions and convenient adjustment of the mixed particle size of cement polymers, and compared with the traditional cement pouring device for bridge construction, the cement pouring device for bridge construction has the following two advantages in specific use:

at first add driving motor at the injection end, the driving motor output shaft is connected with the injection pipe meshing, drives the injection pipe and rotates to make injection angle can 360 degrees change, carry out the regulation of angle according to actual need, improve and pour efficiency.

Secondly, cement is firstly stirred before the material is fed into the pouring pump, the granularity is controlled through the adjusting tank, different pouring operations are met according to the actual required cement granularity, and the overall pouring efficiency is further improved.

Description of the drawings:

for ease of illustration, the invention is described in detail by the following detailed description and the accompanying drawings.

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

FIG. 2 is a schematic view of the wheel mounting structure of the present invention;

FIG. 3 is a schematic view of a second motor mounting arrangement of the present invention;

FIG. 4 is a schematic view of a first spray pipe mounting structure according to the present invention;

FIG. 5 is a schematic view of a spacing groove structure according to the present invention;

FIG. 6 is a schematic structural diagram of a stirring mechanism according to the present invention;

fig. 7 is a schematic view of the structure of the blanking hole and the feed through hole of the invention.

In the figure: 1. a housing mechanism; 11. a housing; 12. a visible glass; 13. a poking groove; 14. a feeding port; 15. a wheel; 16. a connecting shaft; 17. a rotating ring; 18. a support bar; 2. supporting the traction mechanism; 21. a first connecting piece; 22. a fixing ring; 23. an L-shaped connecting plate; 24. a worm gear housing; 25. a screw rod; 26. a top cap; 27. a support plate; 28. a first motor; 29. a second connecting sheet; 210. a connecting seat; 211. a screw head; 3. a pouring mechanism; 31. pouring a pump; 32. a material storage port; 33. a butterfly valve; 34. a discharge port; 35. a main injection pipe; 36. a first material spraying pipe; 361. a rotating groove; 362. an inner tank; 37. a second motor; 38. a meshing shaft; 39. a second material spraying pipe; 310. a first rotating member; 311. a limiting groove; 312. a second rotating member; 313. a connecting rod; 4. a stirring mechanism; 41. a stirring chamber; 42. a third motor; 43. a drive shaft; 44. a stirring roller; 45. a discharge chamber; 46. a material pumping pipe; 47. a suction hole; 48. an adjustment chamber; 49. an adjusting disk; 410. adjusting a rod; 411. a poke rod; 412. a bearing; 413. a blanking hole; 414. and (7) a material passing hole.

The specific implementation mode is as follows:

as shown in fig. 1 to 7, the following technical solutions are adopted in the present embodiment:

the utility model provides a bridge construction is with cement pouring equipment, includes shell mechanism 1, supports drive mechanism 2, pours mechanism 3 and rabbling mechanism 4, 1 both sides of shell mechanism fixed mounting respectively have support drive mechanism 2 and pour mechanism 3, fixed mounting has rabbling mechanism 4 in the 1 inner chamber of shell mechanism.

Wherein, the shell mechanism 1 comprises a shell 11, visual glass 12, a toggle groove 13, a feeding port 14, wheels 15, a connecting shaft 16, a rotating ring 17 and a supporting rod 18, hollow grooves are respectively arranged at two sides of the shell 11, two visual glasses 12 are respectively embedded and installed in the two hollow grooves, the two visual glasses 12 are respectively designed to be matched with the specifications of the two hollow grooves, the toggle groove 13 is arranged at one side of the shell 11 through an inner cavity, the feeding port 14 is arranged at the upper end of the shell 11, the feeding port 14 is communicated with the inner cavity of the shell 11, the wheels 15 are arranged below the shell 11, the two wheels 15 are in the same specification and are symmetrically distributed with each other along a transverse central line of the lower end surface of the shell 11, the circle centers of the two wheels 15 at the opposite sides are fixedly connected through the connecting shaft 16, the connecting shaft 16 is rotatably sleeved with the two rotating rings 17, the two rotating rings 17 are fixedly connected with the lower end surface of the shell 11 through two support rods 18 respectively.

Wherein, the supporting and traction mechanism 2 comprises a first connecting plate 21, a fixing ring 22, an L-shaped connecting plate 23, a worm gear shell 24, a screw rod 25, a top cap 26, a supporting plate 27, a first motor 28, a second connecting plate 29, a connecting seat 210 and a screw head 211, the first connecting plate 21 is fixedly arranged on one side of the shell mechanism 1, the fixing ring 22 is fixedly connected on one side of the first connecting plate 21, the L-shaped connecting plate 23 is fixedly arranged on the edge of one side of the shell mechanism 1, the worm gear shell 24 is fixedly arranged on the inner side edge of the L-shaped connecting plate 23, a worm gear is rotatably arranged in the worm gear shell 24, the screw rod 25 is in threaded connection with the worm gear output end, the top cap 26 is fixedly arranged on the upper top end of the screw rod 25, the supporting plate 27 is arranged under the L-shaped connecting plate 23, and the lower end of the screw rod 25 passes, the L-shaped connecting plate 23 is provided with a first motor 28 in an embedded mode, the output end of the first motor 28 is fixedly connected with a worm, the worm is meshed with the input end of a worm wheel, one side of the L-shaped connecting plate 23 is fixedly provided with a connecting seat 210 through a second connecting piece 29, and the end portion of the connecting seat 210 is fixedly provided with a threaded head 211.

Wherein, the pouring mechanism 3 comprises a pouring pump 31, a material storage port 32, a butterfly valve 33, a material outlet 34, a main material injection pipe 35, a first material injection pipe 36, a rotating groove 361, an inner groove 362, a second motor 37, an engaging shaft 38, a second material injection pipe 39, a first rotating member 310, a limiting groove 311 and a second rotating member 312, the pouring pump 31 is provided with two output ends, the lower end of the pouring pump 31 is fixedly connected with the material storage port 32, one of the output ends is communicated with the material storage port 32, the lower end of the material storage port 32 is fixedly connected with the material outlet 34, the material outlet 34 is communicated with the material storage port 32, the butterfly valve 33 is installed at the joint of the material outlet 34 and the material storage port 32, the main material injection pipe 35 is arranged at one side of the pouring pump 31, the first material injection pipe 36 is communicated with one side of the main material injection pipe 35, the inner cavity of the first material injection pipe 36 is provided with the rotating, a second motor 37 is fixedly mounted on one side of the pouring pump 31, an output end of the second motor 37 is fixedly connected with an engaging shaft 38, the engaging shaft 38 is engaged with the first spraying pipe 36, the other output end of the pouring pump 31 is fixedly communicated with a second spraying pipe 39, an end of the second spraying pipe 39 is fixedly connected with a first rotating member 310, the first rotating member 310 and the rotating groove 361 are designed in an adaptive mode and are arranged correspondingly, a through hole penetrates through the center positions of two opposite sides of the first rotating member 310, a limiting groove 311 is formed in one side of the pouring pump 31, a second rotating member 312 is arranged in the limiting groove 311, and one side of the second rotating member 312 is fixedly connected with one side of the main spraying pipe 35 through a connecting rod 313.

Wherein, be provided with rabbling mechanism 4 in the 1 inner chamber of shell mechanism, be provided with stirring chamber 41 in the rabbling mechanism 4, the last top surface central point of stirring chamber 41 inner chamber puts fixed mounting has third motor 42, third motor 42 output end fixedly connected with driving shaft 43, the fixed cover is equipped with stirring roller 44 on driving shaft 43, discharge chamber 45 has been seted up to 4 lower extremes of rabbling mechanism, be equipped with pumping pipe 46 in the discharge chamber 45, pumping pipe 46 one end and pouring pump 31 input intercommunication, regulation chamber 48 has been seted up between stirring chamber 41 and the discharge chamber 45, be provided with adjusting disk 49 in the regulation chamber 48, the upper and lower terminal surface central point of adjusting disk 49 puts respectively fixed mounting and has adjusting lever 410, adjusting disk 49's outer arc limit fixedly connected with poker rod 411, poker rod 411 one end sets up in the spout 13.

The central positions of the upper cavity wall and the lower cavity wall of the adjusting cavity 48 are fixedly provided with bearings 412, the bottom of the lower cavity of the stirring cavity 41 and the top of the upper cavity of the discharging cavity 45 respectively penetrate through the adjusting cavity 48 and are provided with blanking holes 413, the blanking holes 413 are divided into two layers, and the two layers of the blanking holes 413 are correspondingly arranged between the holes.

A plurality of material passing holes 414 are formed between the upper disc surface and the lower disc surface of the adjusting disc 49 in a penetrating manner, and the material passing holes 414 are respectively matched with the plurality of blanking holes 413 on the two layers and are correspondingly arranged in position.

Wherein, the adjusting disk 49 is rotatably installed with the upper and lower chamber walls of the adjusting chamber 48 through two adjusting rods 410 and two bearings 412.

Wherein, two opposite outer side arc walls of the material pumping pipe 46 respectively penetrate through the pipe cavity and are provided with material sucking holes 47, the material sucking holes 47 are divided into two rows, and the material sucking holes 47 in each row are arranged at equal intervals.

The using state of the invention is as follows: firstly, injecting a proper amount of cement raw materials into the inner cavity of the shell 11 through the material inlet 14, stirring the poke rod 411, adjusting the adjusting disc 49 to block the two layers of blanking holes 413, then starting the third motor 42, driving the stirring roller 44 to stir the cement raw materials through the driving shaft 43 to ensure that the granularity of the cement raw materials can reach the actual requirement, stirring the poke rod 411, adjusting the adjusting disc 49 to align the material through holes 414 with the two layers of blanking holes 413, dropping the cement polymers into the material discharging cavity 45, starting the pouring pump 31, sucking the cement polymers in the material discharging cavity 45 through the material sucking pipe 46, opening the butterfly valve 33, starting the pouring operation on the ground through the material outlet 34, connecting the support traction mechanism 2 with an external dragging mechanism through the threaded head 211 to drive the whole device to move, thereby realizing the movable pouring, starting the second motor 37, driving the first material spraying pipe 36 to rotate through the meshing shaft 38, thereby drive main spraying pipe 35 and do the circular motion around second spraying pipe 39, accomplish the pouring of multi-angle and spout, improved holistic efficiency of pouring.

While there have been shown and described what are at present considered to be the fundamental principles of the invention and its essential features and advantages, it will be understood by those skilled in the art that the invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents.

Claims

1. The cement pouring equipment for bridge construction is characterized by comprising a shell mechanism (1), a supporting and traction mechanism (2), a pouring mechanism (3) and a stirring mechanism (4), wherein the supporting and traction mechanism (2) and the pouring mechanism (3) are fixedly installed on two sides of the shell mechanism (1) respectively, and the stirring mechanism (4) is fixedly installed in an inner cavity of the shell mechanism (1);

the pouring mechanism (3) comprises a pouring pump (31), a material storage port (32), a butterfly valve (33), a material outlet (34), a main material injection pipe (35), a first material injection pipe (36), a rotating groove (361), an inner groove (362), a second motor (37), a meshing shaft (38), a second material injection pipe (39), a first rotating part (310), a limiting groove (311) and a second rotating part (312), wherein the pouring pump (31) is provided with two output ends, the lower end of the pouring pump (31) is fixedly connected with the material storage port (32), one of the output ends is communicated with the material storage port (32), the lower end of the material storage port (32) is fixedly connected with the material outlet (34), the material outlet (34) is communicated with the material storage port (32), the butterfly valve (33) is installed at the joint of the material outlet (34) and the material storage port (32), one side of the pouring pump (31) is provided with the main material, one side of the main spray pipe (35) is communicated with a first spray pipe (36), a rotating groove (361) and an inner groove (362) are arranged in the inner cavity of the first spray pipe (36), the inner groove (362) and the rotating groove (361) are communicated, one side of the pouring pump (31) is fixedly provided with a second motor (37), the output end of the second motor (37) is fixedly connected with a meshing shaft (38), the meshing shaft (38) is meshed with the first spray pipe (36), the other output end of the pouring pump (31) is fixedly communicated with a second spray pipe (39), the end part of the second spray pipe (39) is fixedly connected with a first rotating piece (310), the first rotating piece (310) and the rotating groove (361) are designed in a matched mode and are arranged correspondingly, through holes are formed in the center positions of two opposite side edges of the first rotating piece (310), one side of the pouring pump (31) is provided with a limiting groove (311), and a second rotating part (312) is arranged in the limiting groove (311), and one side of the second rotating part (312) is fixedly connected with one side of the main spray pipe (35) through a connecting rod (313).

2. The cement pouring equipment for bridge construction according to claim 1, wherein: the shell mechanism (1) comprises a shell (11), visual glass (12), a toggle groove (13), a feeding port (14), wheels (15), a connecting shaft (16), a rotating ring (17) and a supporting rod (18), wherein hollow grooves are formed in two sides of the shell (11), the two visual glass (12) are embedded in the two hollow grooves respectively, the two visual glass (12) are designed to be matched with the specifications of the two hollow grooves respectively, the toggle groove (13) is formed in one side of the shell (11) in a penetrating mode and penetrates through an inner cavity, the feeding port (14) is formed in the upper end of the shell (11), the feeding port (14) is communicated with the inner cavity of the shell (11), the wheels (15) are arranged below the shell (11), the two wheels (15) are arranged in a total, the specifications of the two wheels (15) are consistent, and are mutually and are symmetrically distributed on a transverse central line axis of the lower end face of, the two wheels (15) are fixedly connected between the circle centers on the opposite sides through a connecting shaft (16), the connecting shaft (16) is rotatably sleeved with two rotating rings (17), and the two rotating rings (17) are fixedly connected with the lower end face of the shell (11) through two supporting rods (18).

3. The cement pouring equipment for bridge construction according to claim 1, wherein: the supporting and traction mechanism (2) comprises a first connecting piece (21), a fixing ring (22), an L-shaped connecting plate (23), a worm gear shell (24), a screw rod (25), a top cap (26), a supporting plate (27), a first motor (28), a second connecting plate (29), a connecting seat (210) and a screw head (211), wherein the first connecting piece (21) is fixedly arranged on one side of the shell mechanism (1), the fixing ring (22) is vertically and fixedly connected on one side of the first connecting piece (21), the L-shaped connecting plate (23) is vertically and fixedly arranged on the corner of one side of the shell mechanism (1), the worm gear shell (24) is fixedly arranged on the inner side edge of the L-shaped connecting plate (23), a worm gear is rotatably arranged in the worm gear shell (24), the worm gear output end of the worm gear is in threaded connection with the screw rod (25), and the top cap (26), be provided with backup pad (27) under L type connecting plate (23), lead screw (25) lower extreme passes L type connecting plate (23) and backup pad (27) up end central point and puts fixed connection, first motor (28) are installed in the embedding on L type connecting plate (23), first motor (28) output end fixedly connected with worm, the worm is connected with the worm wheel input meshing, there is connecting seat (210) L type connecting plate (23) one side through second connection piece (29) fixed mounting, the tip fixed mounting of connecting seat (210) has screw head (211).

4. The cement pouring equipment for bridge construction according to claim 1, wherein: the stirring mechanism (4) is arranged in an inner cavity of the shell mechanism (1), a stirring cavity (41) is arranged in the stirring mechanism (4), a third motor (42) is fixedly arranged at the center position of the upper top surface of the inner cavity of the stirring cavity (41), an output end of the third motor (42) is fixedly connected with a driving shaft (43), a stirring roller (44) is fixedly sleeved on the driving shaft (43), a discharging cavity (45) is formed at the lower end of the stirring mechanism (4), a material pumping pipe (46) is arranged in the discharging cavity (45), one end of the material pumping pipe (46) is communicated with the input end of the pouring pump (31), an adjusting cavity (48) is formed between the stirring cavity (41) and the discharging cavity (45), an adjusting disc (49) is arranged in the adjusting cavity (48), and adjusting rods (410) are respectively and fixedly arranged at the center positions of the upper end surface and the lower, the outer arc edge of adjusting disk (49) is fixedly connected with poker rod (411), poker rod (411) one end sets up in stirring groove (13).

5. The cement pouring equipment for bridge construction according to claim 4, wherein: the center position of adjusting chamber wall about (48) puts equal fixed mounting has bearing (412), stirring chamber (41) lower chamber end and row material chamber (45) epicoele top run through respectively and adjust chamber (48) and seted up unloading hole (413), and is a plurality of unloading hole (413) divide into two-layerly, two-layerly corresponding setting between unloading hole (413) hole and the hole.

6. The cement pouring equipment for bridge construction according to claim 4, wherein: a plurality of material passing holes (414) are formed between the upper disc surface and the lower disc surface of the adjusting disc (49) in a penetrating mode, and the material passing holes (414) are matched with the material discharging holes (413) in the two layers respectively and are arranged in a corresponding mode.

7. The cement pouring equipment for bridge construction according to claim 4, wherein: the adjusting disc (49) is rotatably arranged with the upper cavity wall and the lower cavity wall of the adjusting cavity (48) through two adjusting rods (410) and two bearings (412).

8. The cement pouring equipment for bridge construction according to claim 4, wherein: two outer arc walls of the material pumping pipe (46) penetrate through the pipe cavity respectively to be provided with material sucking holes (47), the material sucking holes (47) are divided into two rows, and the material sucking holes (47) in each row are arranged at equal intervals.