CN113445506A

CN113445506A - Concrete pouring equipment for dam forming

Info

Publication number: CN113445506A
Application number: CN202110778665.5A
Authority: CN
Inventors: 戴宾洋
Original assignee: Jiangsu Yushun Construction Engineering Co ltd
Current assignee: Jiangsu Yushun Construction Engineering Co ltd
Priority date: 2021-07-09
Filing date: 2021-07-09
Publication date: 2021-09-28
Anticipated expiration: 2041-07-09
Also published as: CN113445506B

Abstract

The invention discloses concrete pouring equipment for dam forming, which comprises a bottom plate, a rectangular pipe, a transmission assembly and a vibrating assembly, wherein the rectangular pipe is fixedly arranged on the bottom plate, the transmission assembly is arranged in the rectangular pipe, the vibrating assembly is fixedly connected to the transmission assembly, when concrete is poured in a template, the concrete can be prevented from falling off through a baffle plate, so that the concrete can push the baffle plate to drive a rotating shaft to rotate, a main gear can synchronously rotate along with the rotating shaft, the main gear can drive a driven gear to rotate through a toothed chain when rotating, the driven gear can drive a lug to rotate through a rotating column, the lug can extrude a top block to transversely move when rotating, the top block can drive a movable plate to longitudinally linearly move through a linkage rod while horizontally moving, and the movable plate can drive the vibrating plate to synchronously move in a vibrating hole through a connecting rod, thereby vibrating the concrete which is just poured.

Description

Concrete pouring equipment for dam forming

Technical Field

The invention relates to the technical field of concrete pouring of constructional engineering, in particular to concrete pouring equipment for dam forming.

Background

Need carry out concrete placement when hydraulic engineering dam shaping construction, concrete placement need use concrete transportation pump truck usually, can pass through the conveying pipeline with the concrete through the pump truck and carry the domatic template of dam in, because the template upper berth is equipped with the slide rail for the bottom plate can remove in the slide rail, thereby can drive the conveying pipeline and remove the template and pour.

Current concrete placement equipment for dam shaping is to when removing to the template and pour, because there is the gap between the stone in the concrete, concrete placement can not get timely vibration in the template and can produce the bubble, the existence of bubble can cause the concrete to compress loosely for the concrete product breaks easily, lead to the engineering quality to receive the influence, consequently need artifical manual work to vibrate again on the concrete, it is hard to take trouble, and intensity of labour is big, can influence the engineering progress.

Disclosure of Invention

The invention aims to provide concrete pouring equipment for dam forming, which aims to solve the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: a concrete pouring device for dam forming comprises a bottom plate, a discharge hole, a rectangular pipe, a feed hole, a connecting pipe, a conveying pipe, a guide box, support rods, a transmission assembly and a vibrating assembly, wherein the discharge hole is formed in one side of the upper end of the bottom plate, the concrete is conveniently moved and poured through the discharge hole, the rectangular pipe is fixedly installed on the bottom plate, the feed hole is formed in the top of the upper end of the rectangular pipe, the connecting pipe is fixedly connected into the feed hole, the conveying pipe is connected to the upper flange of the connecting pipe, the connecting strength between the conveying pipe and the feed hole can be enhanced through the connecting pipe, the guide box is fixedly installed at the bottom of the rectangular pipe, the guide box is an inverted terrace, the lower port of the guide box is in seamless connection with the discharge hole, the concrete can be completely guided into the discharge hole, the support rods are fixedly installed between the two sides of the guide box and the upper surface of the bottom plate, the guide box is supported and fixed through the supporting rods, the stability of the rectangular pipe can be guaranteed, a transmission assembly is arranged in the rectangular pipe, kinetic energy of concrete passing through the rectangular pipe can be utilized to provide power for the vibrating assembly through the transmission assembly, the vibrating assembly is fixedly connected with the vibrating assembly, the vibrating assembly can vibrate concrete which is just poured, and therefore air bubbles generated during concrete pouring can be reduced.

As the preferred technical scheme, the transmission assembly comprises a first rotary hole, an opening, a rotary shaft, a baffle, a main gear, a working box, a second rotary hole, a bearing, a rotary column, a driven gear and a toothed chain;

the front and back of the rectangular pipe are symmetrically provided with a first rotating hole, one side of the rectangular pipe is provided with a hole, the baffle can be prevented from being blocked when rotating along with the rotating shaft through the hole, the rotating shaft is rotatably installed in the first rotating hole, the baffle is vertically installed on the rotating shaft and is positioned in the rectangular pipe, the baffle can block the falling of concrete, so that the concrete can push the baffle to rotate the rotating shaft, main gears are fixedly installed at the two ends of the rotating shaft and can synchronously rotate along with the rotating shaft, one side of the rectangular pipe is fixedly provided with a working box, rotary holes II are symmetrically formed in the front and back of the working box, bearings are fixedly installed in the rotary holes II, rotary columns are fixedly installed in the bearings, the rotary friction force of the rotary columns can be weakened through the bearings, and the rotary columns can more easily rotate in the rotary holes II, the tip fixed mounting of rotary column has driven gear, the master gear is connected through the toothed chain with driven gear, because master gear and driven gear all mesh with the toothed chain mutually, the master gear can drive driven gear through the toothed chain and rotate when rotatory, and then lets driven gear drive rotary column at two internal rotations in the commentaries on classics hole.

As a preferred technical scheme, the transmission assembly further comprises an inclined block, the baffle is fixedly provided with the inclined block, the inclined block is a triangular block, the sharp corner is outward, concrete can be removed favorably through the inclined plane of the inclined block, and the concrete is prevented from being accumulated on the baffle.

As a preferred technical scheme, the vibrating assembly comprises a convex block, a telescopic rod, a top block, a supporting spring, a moving plate, a stud, a linkage rod, a through hole, a nut, a rotary handle, a connecting rod, a vibrating plate and a vibrating hole;

the lifting device is characterized in that a convex block is fixedly arranged between the rotary columns, the convex block is 8-shaped, the upper end and the lower end of the convex block are wide, the middle of the convex block is narrow, the top block can move along the outline of the convex block along with the rotation of the rotary columns through the convex block, telescopic rods are symmetrically and fixedly arranged in the middle of two sides of the inner part of the working box, the top block is fixedly arranged at the telescopic end of the telescopic rod, the transverse movement of the top block can be prevented from being blocked while the top block can be fixed through the telescopic rods, the top block is in contact with the side wall of the convex block, a supporting spring is fixedly arranged on the telescopic rod, the left end of the supporting spring is fixedly connected to the inner wall of the working box, the right end of the supporting spring is fixedly connected to the top block, the top block can be always attached to the side wall of the convex block through the elastic action of the supporting spring, a movable plate is arranged under the convex block, and studs are symmetrically and fixedly arranged around the top block and the rotary columns, the stud is fixedly connected with a linkage rod, both ends of the linkage rod are provided with through holes, the stud penetrates through the through holes and is locked by a nut, the nuts are symmetrically provided with the rotating handles, the rotation of the rotating handles is beneficial to driving the nuts to rotate, so that the linkage rod is locked on the stud, because the stud is in rotating fit with the through hole, the linkage rod can rotate on the stud, the interlocking phenomenon between the top block and the linkage rod when moving is avoided, and the longitudinal movement of the moving plate is also facilitated to be driven by the linkage rod, the bottom of the moving plate is fixedly provided with a connecting rod, the bottom of the connecting rod is fixedly connected with a vibrating plate, the bottom plate is provided with vibrating holes, the vibrating holes are positioned under the vibrating plate, and the vibrating plate is positioned at the bottom of the vibrating hole, and the moving plate can drive the vibrating plate to synchronously move in the vibrating hole through the connecting rod, so that the concrete just poured can be vibrated.

As a preferred technical scheme, the vibration assembly further comprises a rolling groove and a ball, the rolling groove is formed in the middle of one side of the top block, the ball is embedded in the rolling groove in a rolling mode, the ball is in contact with the side wall of the bump, and the ball can roll in the rolling groove and can convert the surface contact of the top block and the bump into point contact, so that the moving friction force between the top block and the bump is reduced, the bump is facilitated to push the bump to move transversely when rotating, and the top block can smoothly move along the contour of the bump.

As preferred technical scheme, fixedly connected with restriction subassembly on the subassembly vibrates, can ensure through the restriction subassembly that the movable plate can not take place to rock when removing, and vibrate and be provided with the adjustment subassembly on the subassembly, be convenient for change the vibrating plate according to the area that the concrete needs vibrate through the adjustment subassembly.

As the preferred technical scheme, the limiting assembly comprises a fixed rod, a sliding block, a sliding hole, a cross rod and a connecting rod;

the utility model discloses a slide mechanism, including bottom plate and movable plate, the bottom plate is equipped with the dead lever around the bottom of work box, the dead lever can play the supporting role to the work box, slidable mounting has the slider on the dead lever, the slide opening has been seted up on the slider, the dead lever runs through the slide opening, is sliding fit through dead lever and slide opening for the slider can carry out longitudinal movement on the dead lever, fixed mounting has the horizontal pole between the slider, can make the slider of both sides carry out the simultaneous movement through the horizontal pole, fixedly connected with connecting rod between the front and back terminal surface of horizontal pole and movable plate makes things convenient for the movable plate to spur the horizontal pole when removing and carries out the simultaneous movement through the connecting rod, thereby makes the horizontal pole drive the slider carry out the longitudinal sliding, can ensure that the movable plate can not take place to rock when longitudinal movement.

As a preferred technical scheme, the adjusting component comprises a connecting sleeve, a connecting block, a rotating rod and a connecting groove;

the lower part of connecting rod is equipped with the screw thread, and the lower part threaded connection of connecting rod has the adapter sleeve, the bottom fixedly connected with connecting block of adapter sleeve, the connecting block is the cylinder piece, and is equipped with the screw thread on the lateral wall of connecting block, the bilateral symmetry fixed mounting and the swing arm of adapter sleeve, the spread groove has been seted up to the upper surface of the board of pounding in a mortar, the spread groove is the thread groove, connecting block and spread groove threaded connection through clockwise promotion swing arm, can let the swing arm drive the adapter sleeve and carry out clockwise rotation to make the adapter sleeve drive the connecting block and shift up in the lower part of connecting rod, meanwhile, the connecting block breaks away from in the spread groove gradually along with the adapter sleeve pivoted, and then makes things convenient for the constructor to change suitable board of pounding in accordance with concrete placement's area.

Compared with the prior art, the invention has the following beneficial effects:

1. the transmission component and the vibrating component are arranged, when concrete is poured into the template, the concrete is transported into the rectangular pipe through the material conveying pipe, the falling of the concrete can be prevented through the baffle plate, thereby the concrete can push the baffle plate to drive the rotating shaft to rotate, and the main gear can synchronously rotate along with the rotating shaft, because the main gear and the driven gear are meshed with the toothed chain, the main gear can drive the driven gear to rotate through the toothed chain when rotating, the driven gear drives the lug to rotate through the rotary column, the lug can extrude the ejector block to move transversely when rotating, the ejector block can horizontally move, the movable plate can be driven to do longitudinal linear motion through the linkage rod, and the movable plate can drive the vibrating plate to do synchronous motion in the vibrating hole through the connecting rod, so that concrete just poured can be vibrated.

2. Utilize the restriction subassembly, make things convenient for the movable plate to stimulate the horizontal pole when removing through the connecting rod and carry out synchronous motion to make the horizontal pole drive the slider and carry out longitudinal sliding on the dead lever, can ensure that the movable plate can not take place to rock when longitudinal movement.

3. Be provided with the adjustment subassembly, through the clockwise swing arm that promotes, can let the swing arm drive the adapter sleeve and carry out clockwise rotation to make the adapter sleeve drive the connecting block and shift up in the lower part of connecting rod, meanwhile, the connecting block breaks away from in the spread groove gradually along with the adapter sleeve pivoted in, and then makes things convenient for constructor to change suitable vibrating plate according to concrete placement's area.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

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

FIG. 2 is a schematic front view of the present invention;

FIG. 3 is a schematic diagram of the right-hand side view of the present invention;

FIG. 4 is a front view cut-away schematic of the present invention;

FIG. 5 is a left side sectional view of the present invention;

FIG. 6 is an enlarged schematic view of FIG. 5 at a;

FIG. 7 is an enlarged view of the structure at b of FIG. 4;

fig. 8 is an enlarged schematic view of the structure at c of fig. 4.

In the figure: 1. a base plate; 2. a discharge hole; 3. a rectangular tube; 4. a feed port;

5. a connecting pipe; 6. a delivery pipe; 7. a guide box; 8. a support bar;

9. a transmission assembly; 901. rotating the first hole; 902. opening a hole; 903. a rotating shaft;

904. a baffle plate; 905. a main gear; 906. a work box; 907. rotating the hole II;

908. a bearing; 909. turning the column; 910. a driven gear; 911. a toothed chain;

912. a sloping block;

10. a vibrating assembly; 1001. a bump; 1002. a telescopic rod; 1003. a top block;

1004. a support spring; 1005. moving the plate; 1006. a stud; 1007. a linkage rod;

1008. perforating; 1009. a nut; 1010. turning a handle; 1011. a connecting rod;

1012. vibrating a plate; 1013. vibrating the hole; 1014. rolling a groove; 1015. a ball bearing;

11. a restraining component; 1101. fixing the rod; 1102. a slider; 1103. a slide hole;

1104. a cross bar; 1105. a connecting rod;

12. an adjustment assembly; 1201. connecting sleeves; 1202. connecting blocks; 1203. rotating the rod;

1204. and connecting the grooves.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example (b): as shown in fig. 1 to 8, the present invention provides the following technical solutions: a concrete pouring device for dam forming comprises a bottom plate 1, a discharge hole 2, a rectangular pipe 3, a feed hole 4, a connecting pipe 5, a material conveying pipe 6, a guide box 7, a support rod 8, a transmission component 9 and a vibrating component 10, wherein the discharge hole 2 is formed in one side of the upper end of the bottom plate 1, the rectangular pipe 3 is conveniently moved and poured through the discharge hole 2, the rectangular pipe 3 is fixedly installed on the bottom plate 1, the feed hole 4 is formed in the top of the upper end of the rectangular pipe 3, the connecting pipe 5 is fixedly connected in the feed hole 4, the material conveying pipe 6 is connected to the connecting pipe 5 in a flange mode, the connecting strength between the material conveying pipe 6 and the feed hole 4 can be enhanced through the connecting pipe 5, the guide box 7 is fixedly installed at the bottom of the rectangular pipe 3, the guide box 7 is an inverted terrace, and the lower port of the guide box 7 is in seamless connection with the discharge hole 2, can get into discharge opening 2 with the whole guides of concrete, fixed mounting has bracing piece 8 between the both sides of guide case 7 all with the upper surface of bottom plate 1, supports fixedly guide case 7 through bracing piece 8, can ensure the stability of rectangular pipe 3, be provided with drive assembly 9 in the rectangular pipe 3, kinetic energy when can utilizing concrete to pass through rectangular pipe 3 in through drive assembly 9 comes for the subassembly 10 that vibrates provides power, fixedly connected with subassembly 10 that vibrates on the drive assembly 9, subassembly 10 that vibrates can vibrate the concrete of just pouring to the bubble that produces when can reducing concrete placement.

As shown in fig. 1-6, the transmission assembly 9 includes a first rotary hole 901, an opening 902, a rotary shaft 903, a baffle 904, a main gear 905, a work box 906, a second rotary hole 907, a bearing 908, a rotary column 909, a driven gear 910, and a toothed chain 911;

the front and back of the rectangular pipe 3 are symmetrically provided with a first rotating hole 901, one side of the rectangular pipe 3 is provided with an opening 902, the opening 902 can ensure that the baffle 904 can not be blocked when rotating along with the rotating shaft 903, the rotating shaft 903 is rotatably installed in the first rotating hole 901, the baffle 904 is vertically installed on the rotating shaft 903, the baffle 904 is positioned in the rectangular pipe 3 and can block the falling of concrete through the baffle 904, so that the concrete can push the baffle 904, the rotating shaft 903 rotates, the two ends of the rotating shaft 903 are fixedly provided with a main gear 905, the main gear 905 can synchronously rotate along with the rotating shaft 903, one side of the rectangular pipe 3 is fixedly provided with a working box 906, the front and back of the working box 906 are symmetrically provided with a second rotating hole 907, a bearing 908 is fixedly installed in the second rotating hole 907, a rotating column 909 is fixedly installed in the bearing 908, and the rotating friction force of the rotating column 909 can be weakened through the bearing, the rotary column 909 can rotate in the second rotary hole 907 more easily, a driven gear 910 is fixedly mounted at an end of the rotary column 909, the main gear 905 and the driven gear 910 are connected through a toothed chain 911, and since the main gear 905 and the driven gear 910 are both meshed with the toothed chain 911, the main gear 905 can drive the driven gear 910 to rotate through the toothed chain 911 during rotation, so that the driven gear 910 can drive the rotary column 909 to rotate in the second rotary hole 907.

The transmission assembly 9 further comprises an inclined block 912, the inclined block 912 is fixedly mounted on the baffle 904, the inclined block 912 is a triangular block, the sharp corner is outward, concrete can be removed through the inclined surface of the inclined block 912, and the concrete is prevented from being accumulated on the baffle 904.

As shown in fig. 1-5 and 7, the vibrating assembly 10 includes a projection 1001, a telescopic rod 1002, a top block 1003, a supporting spring 1004, a moving plate 1005, a stud 1006, a linkage 1007, a through hole 1008, a nut 1009, a rotary handle 1010, a connecting rod 1011, a vibrating plate 1012, and a vibrating hole 1013;

bumps 1001 are fixedly arranged among the rotary columns 909, the bumps 1001 are 8-shaped, the upper ends and the lower ends of the bumps are wide, the middle of the bumps is narrow, the top blocks 1003 can move along the outlines of the bumps 1001 through the rotation of the bumps 1001 along with the rotation of the rotary columns 909, telescopic rods 1002 are symmetrically and fixedly arranged in the middle of two sides of the interior of the work box 906, top blocks 1003 are fixedly arranged at the telescopic ends of the telescopic rods 1002, the top blocks 1003 can be fixed through the telescopic rods 1002, the transverse movement of the top blocks 1003 is not hindered, the top blocks 1003 are in contact with the side walls of the bumps 1001, supporting springs 1004 are fixedly arranged on the telescopic rods 1002, the left ends of the supporting springs 1004 are fixedly connected to the inner wall of the work box 906, the right ends of the supporting springs 1004 are fixedly connected to the top blocks 1003, and the top blocks 1003 can be always attached to the side walls of the bumps 1001 through the elastic force of the supporting springs 1004, a moving plate 1005 is arranged right below the bump 1001, studs 1006 are symmetrically and fixedly mounted on the top block 1003 and the moving plate 1005 in a front-back manner, a linkage 1007 is fixedly connected to the studs 1006, through holes 1008 are formed in both ends of the linkage 1007, the studs 1006 penetrate through the through holes 1008 and are locked by nuts 1009, turning handles 1010 are symmetrically mounted on the nuts 1009, the nuts 1009 are favorable for driving the nuts 1009 to rotate by turning the turning handles 1010, so that the linkage 1007 is locked to the studs 1006, the linkage 1007 can turn on the studs 1006 due to the fact that the studs 1006 and the through holes 1008 are in rotating fit, the top block 1003 and the linkage 1007 are prevented from interlocking when moving, the moving plate 1005 is also favorable for driving the moving plate 1005 to move longitudinally by the linkage 1007, a connecting rod 1011 is fixedly mounted at the bottom of the moving plate 1005, a vibrating plate 1012 is fixedly connected to the bottom of the connecting rod 1011, and vibrating holes 1013 are formed in the bottom plate 1, the vibrating hole 1013 is located right below the vibrating plate 1012, the vibrating plate 1012 is located at the bottom of the vibrating hole 1013, and the moving plate 1005 can drive the vibrating plate 1012 to synchronously move in the vibrating hole 1013 through the connecting rod 1011, so that the concrete just poured can be vibrated.

The vibrating assembly 10 further comprises a rolling groove 1014 and a ball 1015, the rolling groove 1014 is formed in the middle of one side of the top block 1003, the ball 1015 is embedded in the rolling groove 1014 in a rolling manner, the ball 1015 is in contact with the side wall of the bump 1001, and the ball 1015 can roll in the rolling groove 1014, so that the surface contact between the top block 1003 and the bump 1001 can be converted into point contact, the moving friction force between the top block 1003 and the bump 1001 is reduced, the bump 1001 is favorably pushed to move transversely when rotating, and the top block 1003 can smoothly move along the contour of the bump 1001.

Fixedly connected with restriction subassembly 11 on the subassembly 10 vibrates, can ensure through restriction subassembly 11 that the movable plate 1005 can not take place to rock when removing, and is provided with adjustment subassembly 12 on the subassembly 10 vibrates, and the area that is convenient for vibrate according to the concrete needs through adjustment subassembly 12 changes the board 1012 that vibrates.

As shown in fig. 1 to 5, the limiting assembly 11 includes a fixing rod 1101, a slider 1102, a sliding hole 1103, a cross bar 1104 and a connecting rod 1105;

the fixing rods 1101 are symmetrically and fixedly arranged between the bottom plate 1 and the bottom of the work box 906 in a front-back mode, the fixing rods 1101 can support the work box 906, sliding blocks 1102 are arranged on the fixing rods 1101 in a sliding mode, sliding holes 1103 are formed in the sliding blocks 1102, the fixing rods 1101 penetrate through the sliding holes 1103, the fixing rods 1101 are in sliding fit with the sliding holes 1103, the sliding blocks 1102 can move longitudinally on the fixing rods 1101, cross rods 1104 are fixedly arranged between the sliding blocks 1102, the sliding blocks 1102 on two sides can move synchronously through the cross rods 1104, connecting rods 1105 are fixedly connected between the cross rods 1104 and the front end face and the back end face of the moving plate 1005, the moving plate 1005 can be pulled by the connecting rods 1105 to move synchronously when moving, and therefore the cross rods 1104 can drive the sliding blocks 1102 to slide longitudinally, and the moving plate 1005 cannot shake when moving longitudinally.

As shown in fig. 1, 4, 5 and 8, the adjusting assembly 12 includes a connecting sleeve 1201, a connecting block 1202, a rotating rod 1203 and a connecting groove 1204;

the lower portion of the connecting rod 1011 is provided with threads, the lower portion of the connecting rod 1011 is in threaded connection with the connecting sleeve 1201, the bottom of the connecting sleeve 1201 is fixedly connected with the connecting block 1202, the connecting block 1202 is a cylindrical block, threads are formed in the side wall of the connecting block 1202, the two sides of the connecting sleeve 1201 are symmetrically and fixedly installed with the rotating rod 1203, the connecting groove 1204 is formed in the upper surface of the vibrating plate 1012, the connecting groove 1204 is a threaded groove, the connecting block 1202 is in threaded connection with the connecting groove 1204, the rotating rod 1203 is pushed clockwise, the rotating rod 1203 can drive the connecting sleeve 1201 to rotate clockwise, the connecting sleeve 1201 drives the connecting block 1202 to move up on the lower portion of the connecting rod 1011, meanwhile, the connecting block 1202 gradually breaks away from the connecting groove 1204 along with the rotation of the connecting sleeve 1201, and accordingly construction workers can conveniently replace the vibrating plate 1012 according to the area of concrete.

The working principle of the invention is as follows: firstly, when concrete is poured into the formwork, the concrete is transported into the rectangular pipe 3 through the delivery pipe, the falling of the concrete can be prevented through the baffle 904, thereby the concrete can push the baffle 904 to drive the rotating shaft 903 to rotate, and further the main gear 905 can synchronously rotate along with the rotating shaft 903, since the main gear 905 and the driven gear 910 are engaged with the gear chain 911, the main gear 905 can rotate the driven gear 910 by the gear chain 911, the driven gear 910 drives the bump 1001 to rotate through the rotary pillar 909, the bump 1001 can press the top block 1003 to move transversely when rotating, the top block 1003 moves horizontally, the linkage rod 1007 can drive the moving plate 1005 to do longitudinal linear motion, and the moving plate 1005 can drive the vibrating plate 1012 to do synchronous motion in the vibrating hole 1013 through the connecting rod 1011, so that the concrete just poured can be vibrated.

Then, by using the limiting assembly 11, the moving plate 1005 can be conveniently pulled by the connecting rod 1105 to move synchronously when moving, so that the cross rod 1104 drives the slider 1102 to slide longitudinally on the fixed rod 1101, and the moving plate 1005 can be ensured not to shake when moving longitudinally.

Finally, the adjusting assembly 12 is arranged, the rotating rod 1203 is pushed clockwise, the rotating rod 1203 can be enabled to drive the connecting sleeve 1201 to rotate clockwise, so that the connecting sleeve 1201 drives the connecting block 1202 to move upwards on the lower portion of the connecting rod 1011, meanwhile, the connecting block 1202 gradually breaks away from the connecting groove 1204 along with the rotation of the connecting sleeve 1201, and accordingly construction personnel can conveniently replace the appropriate vibrating plate 1012 according to the concrete pouring area.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a concrete placement equipment for dam shaping which characterized in that: the concrete pouring equipment for dam forming comprises a bottom plate (1), discharge holes (2), rectangular pipes (3), feed holes (4), connecting pipes (5), conveying pipes (6), guide boxes (7), support rods (8), a transmission assembly (9) and a vibrating assembly (10), wherein the discharge holes (2) are formed in one side of the upper end of the bottom plate (1), the rectangular pipes (3) are fixedly mounted on the bottom plate (1), the feed holes (4) are formed in the tops of the upper ends of the rectangular pipes (3), the connecting pipes (5) are fixedly connected in the feed holes (4), the conveying pipes (6) are connected to the connecting pipes (5) through flanges, the guide boxes (7) are fixedly mounted at the bottoms of the rectangular pipes (3), the guide boxes (7) are inverted step platforms, lower ports of the guide boxes (7) are connected with the discharge holes (2) in a seamless mode, the support rods (8) are fixedly mounted between the two sides of the guide boxes (7) and the upper surface of the bottom plate (1), the vibrating pipe is characterized in that a transmission assembly (9) is arranged in the rectangular pipe (3), and a vibrating assembly (10) is fixedly connected to the transmission assembly (9).

2. A concrete pouring apparatus for forming a dam as claimed in claim 1, wherein: the transmission assembly (9) comprises a first rotary hole (901), an opening (902), a rotating shaft (903), a baffle (904), a main gear (905), a working box (906), a second rotary hole (907), a bearing (908), a rotary column (909), a driven gear (910) and a toothed chain (911);

the front and back of the rectangular pipe (3) are symmetrically provided with a first rotating hole (901), one side of the rectangular pipe (3) is provided with an opening (902), a rotating shaft (903) is rotatably mounted in the first rotating hole (901), a baffle (904) is vertically mounted on the rotating shaft (903), the baffle (904) is located in the rectangular pipe (3), two ends of the rotating shaft (903) are fixedly provided with a main gear (905), one side of the rectangular pipe (3) is fixedly provided with a working box (906), front and back of the working box (906) are symmetrically provided with a second rotating hole (907), a bearing (908) is fixedly mounted in the second rotating hole (907), a rotating column (909) is fixedly mounted in the bearing (908), a driven gear (910) is fixedly mounted at the end part of the rotating column (909), and the main gear (905) is connected with the driven gear (910) through a toothed chain (911).

3. A concrete pouring apparatus for forming a dam as claimed in claim 2, wherein: the transmission assembly (9) further comprises an inclined block (912), the baffle (904) is fixedly provided with the inclined block (912), the inclined block (912) is a triangular block, and the sharp corner is outward.

4. A concrete pouring apparatus for forming a dam as claimed in claim 1, wherein: the vibrating assembly (10) comprises a bump (1001), a telescopic rod (1002), a top block (1003), a supporting spring (1004), a moving plate (1005), a stud (1006), a linkage rod (1007), a through hole (1008), a nut (1009), a rotary handle (1010), a connecting rod (1011), a vibrating plate (1012) and a vibrating hole (1013);

the rotary type working box is characterized in that a bump (1001) is fixedly installed between the rotary columns (909), the bump (1001) is 8-shaped, telescopic rods (1002) are symmetrically and fixedly installed in the middle parts of two sides in the working box (906), a top block (1003) is fixedly installed at the telescopic end of each telescopic rod (1002), the top block (1003) is in contact with the side wall of the bump (1001), a supporting spring (1004) is fixedly installed on each telescopic rod (1002), the left end of each supporting spring (1004) is fixedly connected to the inner wall of the working box (906), the right end of each supporting spring (1004) is fixedly connected to the top block (1003), a moving plate (1005) is arranged right below each bump (1001), studs (1006) are symmetrically and fixedly installed at the front and the back of each moving plate (1005), a linkage rod (1007) is fixedly connected to each stud (1006), and through holes (1008) are formed in two ends of each linkage rod (1007), the double-screw bolt (1006) run through and perforate (1008) and lock with nut (1009), the symmetry is installed and is revolved handle (1010) on nut (1009), the bottom fixed mounting of movable plate (1005) has connecting rod (1011), the bottom fixedly connected with vibration board (1012) of connecting rod (1011), hole (1013) of vibrating has been seted up on bottom plate (1), hole (1013) of vibrating is located vibration board (1012) under, and vibration board (1012) are located the bottom of hole (1013) of vibrating.

5. The concrete pouring apparatus for forming a dam as claimed in claim 4, wherein: the vibrating assembly (10) further comprises a rolling groove (1014) and a ball (1015), the rolling groove (1014) is formed in the middle of one side of the top block (1003), the ball (1015) is embedded in the rolling groove (1014) in a rolling mode, and the ball (1015) is in contact with the side wall of the bump (1001).

6. A concrete pouring apparatus for forming a dam as claimed in claim 1, wherein: the vibrating component (10) is fixedly connected with a limiting component (11), and the vibrating component (10) is provided with an adjusting component (12).

7. The concrete pouring apparatus for forming a dam as claimed in claim 6, wherein: the limiting assembly (11) comprises a fixing rod (1101), a sliding block (1102), a sliding hole (1103), a cross bar (1104) and a connecting rod (1105);

the utility model discloses a movable plate (1005) is characterized in that fixed rod (1101) is symmetrically and fixedly installed around between the bottom of bottom plate (1) and workbin (906), slidable mounting has slider (1102) on fixed rod (1101), slotted hole (1103) has been seted up on slider (1102), sliding hole (1103) is run through to fixed rod (1101), fixed mounting has horizontal pole (1104) between slider (1102), fixedly connected with connecting rod (1105) between the front and back terminal surface of horizontal pole (1104) and movable plate (1005).

8. The concrete pouring apparatus for forming a dam as claimed in claim 6, wherein: the adjusting component (12) comprises a connecting sleeve (1201), a connecting block (1202), a rotary rod (1203) and a connecting groove (1204);

the utility model discloses a vibrating plate, including connecting rod (1011), connecting sleeve (1201), bottom fixedly connected with connecting block (1202) of connecting sleeve (1201), connecting block (1202) are the cylinder piece, and are equipped with the screw thread on the lateral wall of connecting block (1202), the bilateral symmetry fixed mounting and the swing arm (1203) of connecting sleeve (1201), spread groove (1204) have been seted up to the upper surface of vibrating plate (1012), spread groove (1204) are the thread groove, connecting block (1202) and spread groove (1204) threaded connection.