CN220644071U

CN220644071U - River lining device

Info

Publication number: CN220644071U
Application number: CN202320734112.4U
Authority: CN
Inventors: 张艳斌
Original assignee: Hanting Management Station Of Shandong Water Diversion Project Operation And Maintenance Center
Current assignee: Hanting Management Station Of Shandong Water Diversion Project Operation And Maintenance Center
Priority date: 2023-03-31
Filing date: 2023-03-31
Publication date: 2024-03-22
Anticipated expiration: 2033-03-31

Abstract

The utility model discloses a river lining device, and relates to the technical field of hydraulic engineering. The utility model comprises a fixed template component, a sliding component and a movable template component, wherein the rear side of the fixed template component is connected with the movable template component, a feed box component is arranged right above the fixed template component, the lower parts of the left side and the right side of the feed box component are both connected with a discharging component, and the lower side of the discharging component is connected with the sliding component. According to the utility model, the fixed template assembly and the movable template assembly are arranged, the convex position of the inner side wall of the river channel is scraped and tidied, so that the cast concrete is more attached to the inner side wall of the river channel, the leveling of the surface of the cast concrete is facilitated, and the upper part of the concrete in the river channel is subjected to vibration tamping and leveling treatment through the arranged sliding assembly.

Description

River lining device

Technical Field

The utility model belongs to the technical field of hydraulic engineering, and particularly relates to a river lining device.

Background

The hydraulic engineering is an engineering for constructing hydraulic facilities by controlling and preparing surface water and underground water in the nature so as to achieve the purpose of removing harmful substances; the river course construction that we are common in life is typical hydraulic engineering facility construction process, in order to prevent the loss of the inside earth of river course, constructor can carry out concrete casting in the bottom and the two inside walls of river course, carries out lining processing to the river course inside promptly, and at present, the staff mainly lays the concrete to the river course inside through lining device to the purpose that carries out the lining to the river course is solved.

However, the following drawbacks still exist in practical use:

1. in the working process of the conventional river lining device, a concrete casting space is formed through the templates, so that the cast concrete is more attached to the river, but the protruding soil on the inner side wall of the river cannot be scraped, the flatness of the surface of the cast concrete is further affected, and the attractiveness of the river lining is reduced;

2. current river course lining device is in the in-process of work, drives the template through vibration mechanism and vibrates, vibrates the tamp to the concrete of casting for the concrete of casting is compacter, but can't vibrate the tamp to the upper portion of the inside concrete of river course, and then can't flatten the tamp to the inside concrete upper surface of river course.

Therefore, the conventional river lining device cannot meet the requirements in practical use, so that an improved technology is urgently needed in the market to solve the above problems.

Disclosure of Invention

The utility model aims to provide a river lining device, which solves the problems that the existing river lining device cannot scrape out convex soil on the inner side wall of a river and cannot level and tamp the upper surface of concrete in the river by arranging a fixed template assembly, a movable template assembly and a sliding assembly.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model relates to a river lining device which comprises a fixed template component, a sliding component and a movable template component, wherein the rear side of the fixed template component is connected with the movable template component, a material box component is arranged right above the fixed template component, the lower parts of the left side and the right side of the material box component are both connected with a discharging component, and the lower side of the discharging component is connected with the sliding component.

Further, the fixed template assembly comprises an inverted trapezoid template and a first side template; the front side of the inverted trapezoid template is connected with a first side template, T-shaped through grooves are symmetrically formed in the left and right sides of the upper portion of the first side template, the middle of the upper side of the inverted trapezoid template is connected with a vibrating motor, a triangular bracket is arranged right above the vibrating motor, and three corners of the lower side of the triangular bracket are respectively connected with the left and right inner side walls of the inverted trapezoid template and the rear side of the first side template.

Further, the movable template assembly comprises a second hydraulic cylinder, a U-shaped frame and a second side template; the second side form board is located the reverse trapezoidal template rear side, is connected with the U-shaped frame directly over the second side form board, and second side form board upside middle part is connected with the second pneumatic cylinder, and the U-shaped frame is run through to second pneumatic cylinder upper end, and the U-shaped frame is connected with second pneumatic cylinder periphery.

Further, the feed box assembly comprises a feed hopper and a hopper box; the hopper case is located directly over the trapezoid template, and hopper case downside middle part is connected with the tripod upside, and the hopper case upside is connected with sealed top cap, and sealed top cap upper portion front side intercommunication has the feeder hopper.

Further, the discharging assembly comprises a discharging pipe and a connecting pipe; the two discharging pipes are symmetrically distributed at the lower parts of the left side and the right side of the hopper box, connecting pipes are communicated at equal intervals at the upper parts of the inner sides of the discharging pipes, the inner sides of the connecting pipes are communicated with the lower parts of the left side and the right side of the hopper box, a valve is connected to the connecting pipes, and a U-shaped groove is formed in the front side of each discharging pipe.

Further, the sliding assembly comprises a cross rod and a first hydraulic cylinder; the horizontal pole is located the discharging pipe downside, and the horizontal pole front side runs through U-shaped recess, horizontal pole downside T shape slide bar and T shape logical groove sliding connection, and horizontal pole upper portion front side is connected with L shape seat, and L shape seat rear side is connected with first pneumatic cylinder front end, and symmetrical connection has the mount pad around the first pneumatic cylinder outside.

Further, the middle parts of the left side and the right side of the feed box assembly are connected with supporting assemblies, and the supporting assemblies comprise rollers and L-shaped support plates; the two L-shaped support plates are symmetrically distributed in the middle of the left side and the right side of the hopper box, rollers are distributed on the lower side of the L-shaped support plates at equal intervals, the rear sides of the two L-shaped support plates are respectively connected with the front sides of the U-shaped frames in a left-right mode, and the lower portions of the inner sides of the two L-shaped support plates are respectively connected with the mounting seats in a front-back mode.

Further, the middle part of the upper side of the feed box component is connected with a stirring component, and the stirring component comprises a V-shaped stirring rod, a rotating shaft and a first motor; the first motor is located directly over the seal top cover, and a rotating shaft on the lower side of the first motor penetrates through the middle of the seal top cover, and a V-shaped stirring rod is connected to the lower side of the periphery of the rotating shaft.

The utility model has the following beneficial effects:

1. according to the river channel lining device, the fixed template assembly and the movable template assembly are arranged, so that when the river channel lining device moves, the first side template in the fixed template assembly and the second side template in the movable template assembly scrape the protruding positions on the two inner side walls of a river channel, and further, the paving of concrete on the inner side walls of the river channel is smoother.

2. According to the utility model, the sliding assembly is arranged, so that after the vibrating motor is started, the fixed template assembly and the movable template assembly vibrate and tamp concrete at the bottom and on two inner side walls of the river channel, and meanwhile, the sliding assembly vibrates and tamps the upper part of the concrete in the river channel, so that the concrete in the river channel is comprehensively vibrated and tamped in the working process of the lining device of the river channel.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic structural view of a river lining device;

FIG. 2 is a schematic illustration of the connection of the bin assembly and the support assembly;

FIG. 3 is a schematic structural view of a stirring assembly;

FIG. 4 is a schematic illustration of the connection of the hopper bin and the discharge assembly;

FIG. 5 is a schematic illustration of the connection of the hopper box and fixed die plate assembly;

FIG. 6 is a schematic illustration of the connection of the slide assembly, first side form, L-bracket and spout;

FIG. 7 is a schematic illustration of the connection of the movable platen assembly, inverted trapezoidal template and L-shaped support plate.

In the drawings, the list of components represented by the various numbers is as follows:

1. fixing the template assembly; 11. an inverted trapezoid template; 12. a first side template; 13. t-shaped through grooves; 14. a vibration motor; 15. a tripod; 2. a sliding assembly; 21. a T-shaped slide bar; 22. a cross bar; 23. an L-shaped seat; 24. a mounting base; 25. a first hydraulic cylinder; 3. a support assembly; 31. a roller; 32. an L-shaped support plate; 4. a bin assembly; 41. a feed hopper; 42. sealing the top cover; 43. a hopper box; 5. a stirring assembly; 51. v-shaped stirring rod; 52. a rotating shaft; 53. a first motor; 6. a movable template assembly; 61. a second hydraulic cylinder; 62. a U-shaped frame; 63. a second sideform; 7. a discharge assembly; 71. a valve; 72. a discharge pipe; 73. a connecting pipe; 74. u-shaped recess.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

Referring to fig. 1 to 7, the utility model discloses a river lining device, which comprises a fixed template assembly 1, a sliding assembly 2 and a movable template assembly 6, wherein the rear side of the fixed template assembly 1 is connected with the movable template assembly 6, a feed box assembly 4 is arranged right above the fixed template assembly 1, the lower parts of the left side and the right side of the feed box assembly 4 are respectively connected with a discharge assembly 7, and the lower side of the discharge assembly 7 is connected with the sliding assembly 2;

the user connects the external locomotive with the rear side of the U-shaped frame 62, the river lining device is connected with the external locomotive, the user starts the external locomotive to move the river lining device to the river, the two supporting components 3 are respectively positioned at two sides of the river, and the material box component 4 is positioned right above the river;

the user starts the first hydraulic cylinder 25 to release the blocking of the lower side of the discharging pipe 72 by the cross rod 22;

pouring the concrete from the feed hopper 41 into the hopper box 43 by a user, and starting the stirring assembly 5 to stir the concrete in the hopper box 43 by the user;

the user opens the valve 71, the concrete in the hopper box 43 falls into the river through the discharge pipe 72, and the concrete is distributed on the bottom and the two inner side walls of the river;

the user starts the first hydraulic cylinder 25 again, so that the cross rod 22 plugs the lower side of the discharging pipe 72, the user starts the vibrating motor 14, the fixed template assembly 1 vibrates, the cross rod 22 vibrates, the second side template 63 vibrates, and the concrete falling into the river is comprehensively vibrated and compacted;

when the user needs to move the river lining device to the next station, the user starts the second hydraulic cylinder 61 to drive the second side template 63 to move upwards until the lower side of the second side template 63 moves to a position higher than the upper side of the inverted trapezoid template 11, the user starts the external locomotive again, the supporting component 3 moves to the next station along the two sides of the river, and the river lining device moves to the next station.

As shown in fig. 5, the fixed die plate assembly 1 comprises an inverted trapezoid die plate 11 and a first side die plate 12; the front side of the inverted trapezoid template 11 is connected with a first side template 12, T-shaped through grooves 13 are symmetrically formed in the left and right sides of the upper part of the first side template 12, the middle part of the upper side of the inverted trapezoid template 11 is connected with a vibrating motor 14, a triangular bracket 15 is arranged right above the vibrating motor 14, and three corners of the lower side of the triangular bracket 15 are respectively connected with the left and right inner side walls of the inverted trapezoid template 11 and the rear side of the first side template 12;

the user uses external control end start vibrating motor 14, and the reverse trapezoidal template 11 vibrates, and first side form 12 vibrates and tripod 15 vibrates, vibrates the compaction to the concrete of river course bottom and two inside walls.

Wherein as shown in fig. 7, the movable die plate assembly 6 comprises a second hydraulic cylinder 61, a U-shaped frame 62 and a second side die plate 63; the second side template 63 is positioned at the rear side of the inverted trapezoid template 11, a U-shaped frame 62 is connected right above the second side template 63, a second hydraulic cylinder 61 is connected to the middle part of the upper side of the second side template 63, the upper end of the second hydraulic cylinder 61 penetrates through the U-shaped frame 62, and the U-shaped frame 62 is connected with the periphery of the second hydraulic cylinder 61;

the user starts the second hydraulic cylinder 61 by using the external control end, when the second hydraulic cylinder 61 is contracted, the second side template 63 moves upwards, so that the second side template 63 moves to the upper side of the inverted trapezoid template 11, and the second side template 63 is prevented from obstructing the movement of the inverted trapezoid template 11 in the river; when the second hydraulic cylinder 61 is extended, the second side form 63 moves downward, closing the opening at the rear side of the inverted trapezoidal form 11, and avoiding the concrete from overflowing from the rear side of the inverted trapezoidal form 11.

Wherein, as shown in fig. 2, the feed bin assembly 4 comprises a feed hopper 41 and a hopper bin 43; the hopper box 43 is positioned right above the inverted trapezoid template 11, the middle part of the lower side of the hopper box 43 is connected with the upper side of the triangular bracket 15, the upper side of the hopper box 43 is connected with the sealing top cover 42, and the front side of the upper part of the sealing top cover 42 is communicated with the feed hopper 41;

the user introduces concrete into the hopper 41, and the concrete in the hopper 41 enters the hopper box 43, and when the tripod 15 vibrates, the hopper box 43 vibrates.

Wherein, as shown in fig. 4, the discharging assembly 7 comprises a discharging pipe 72 and a connecting pipe 73; the two discharging pipes 72 are symmetrically distributed at the lower parts of the left side and the right side of the hopper box 43, the upper parts of the inner sides of the discharging pipes 72 are communicated with connecting pipes 73 at equal intervals, the inner sides of the connecting pipes 73 are communicated with the lower parts of the left side and the right side of the hopper box 43, the connecting pipes 73 are connected with valves 71, and the front sides of the discharging pipes 72 are provided with U-shaped grooves 74;

the user opens the valve 71, and the concrete inside the hopper box 43 enters the discharging pipe 72 through the connecting pipe 73, and the concrete inside the discharging pipe 72 falls into the river to internally build the bottom and the two inner side walls of the river.

Wherein, as shown in fig. 6, the sliding assembly 2 comprises a cross bar 22 and a first hydraulic cylinder 25; the cross rod 22 is positioned at the lower side of the discharging pipe 72, the front side of the cross rod 22 penetrates through the U-shaped groove 74, the T-shaped slide rod 21 at the lower side of the cross rod 22 is in sliding connection with the T-shaped through groove 13, the front side of the upper part of the cross rod 22 is connected with the L-shaped seat 23, the rear side of the L-shaped seat 23 is connected with the front end of the first hydraulic cylinder 25, and the outer side of the first hydraulic cylinder 25 is symmetrically connected with the mounting seat 24 in front-rear direction;

when the first hydraulic cylinder 25 stretches, the T-shaped slide bar 21 moves along the T-shaped through groove 13 in a direction away from the first side template 12, the cross bar 22 moves along with the movement of the T-shaped slide bar 21, the L-shaped seat 23 moves along with the movement of the cross bar 22 until the first hydraulic cylinder 25 stretches to the longest, and at the moment, the blocking of the lower side of the discharging pipe 72 by the cross bar 22 is just released; conversely, when the first hydraulic cylinder 25 is contracted, and until the first hydraulic cylinder 25 is contracted to the shortest, the lower side of the discharging pipe 72 is just blocked by the cross bar 22.

As shown in fig. 1 and 2, the middle parts of the left side and the right side of the feed box assembly 4 are connected with a support assembly 3, and the support assembly 3 comprises a roller 31 and an L-shaped support plate 32; the two L-shaped support plates 32 are symmetrically distributed in the middle of the left side and the right side of the hopper box 43, the rollers 31 are distributed on the lower side of the L-shaped support plates 32 at equal intervals, the rear sides of the two L-shaped support plates 32 are respectively connected with the front sides of the U-shaped frames 62 left and right, and the front and rear parts of the lower parts of the inner sides of the two L-shaped support plates 32 are respectively connected with the mounting seats 24;

the user connects the rear side of the U-shaped frame 62 to the external locomotive, the user starts the external locomotive, the rollers 31 move, the support assembly 3 moves, the feed box assembly 4 moves, and the river lining device moves.

As shown in fig. 1 and 3, a stirring assembly 5 is connected to the middle part of the upper side of the feed box assembly 4, and the stirring assembly 5 comprises a V-shaped stirring rod 51, a rotating shaft 52 and a first motor 53; the first motor 53 is positioned right above the seal top cover 42, a rotating shaft 52 at the lower side of the first motor 53 penetrates through the middle part of the seal top cover 42, and a V-shaped stirring rod 51 is connected to the lower side of the periphery of the rotating shaft 52;

the user starts the first motor 53 using the external control terminal, the rotation shaft 52 rotates, and the V-shaped stirring rod 51 rotates to stir the concrete inside the hopper box 43.

The foregoing is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, and any modification, equivalent replacement, and improvement of some of the technical features described in the foregoing embodiments are all within the scope of the present utility model.

Claims

1. River course lining device, including fixed template subassembly (1), slip subassembly (2) and movable mould board subassembly (6), its characterized in that: the automatic feeding device is characterized in that a movable template assembly (6) is connected to the rear side of the fixed template assembly (1), a feed box assembly (4) is arranged right above the fixed template assembly (1), discharging assemblies (7) are connected to the lower portions of the left side and the right side of the feed box assembly (4), and sliding assemblies (2) are connected to the lower sides of the discharging assemblies (7).

2. A river lining apparatus as claimed in claim 1, wherein: the fixed template assembly (1) comprises an inverted trapezoid template (11) and a first side template (12); the novel concrete pouring device is characterized in that the front side of the inverted trapezoid template (11) is connected with the first side template (12), T-shaped through grooves (13) are formed in the left and right sides of the upper portion of the first side template (12) symmetrically, a vibrating motor (14) is connected to the middle of the upper side of the inverted trapezoid template (11), a triangular bracket (15) is arranged right above the vibrating motor (14), and three corners of the lower side of the triangular bracket (15) are respectively connected with the left inner side wall, the right inner side wall and the rear side of the first side template (12) of the inverted trapezoid template (11).

3. A river lining apparatus as claimed in claim 1, wherein: the movable template assembly (6) comprises a second hydraulic cylinder (61), a U-shaped frame (62) and a second side template (63); the second side template (63) is located reverse trapezoidal template (11) rear side, be connected with directly over second side template (63) U-shaped frame (62), second side template (63) upside middle part is connected with second pneumatic cylinder (61), second pneumatic cylinder (61) upper end runs through U-shaped frame (62), just U-shaped frame (62) with second pneumatic cylinder (61) periphery is connected.

4. A river lining apparatus as claimed in claim 1, wherein: the feed box assembly (4) comprises a feed hopper (41) and a hopper box (43); hopper case (43) are located right above reverse trapezoidal template (11), hopper case (43) downside middle part is connected with tripod (15) upside, hopper case (43) upside is connected with sealed top cap (42), sealed top cap (42) upper portion front side intercommunication has feeder hopper (41).

5. A river lining apparatus as claimed in claim 1, wherein: the discharging assembly (7) comprises a discharging pipe (72) and a connecting pipe (73); the two discharging pipes (72) are symmetrically distributed at the lower parts of the left side and the right side of the hopper box (43), the upper parts of the inner sides of the discharging pipes (72) are communicated with the connecting pipes (73) at equal intervals, the inner sides of the connecting pipes (73) are communicated with the lower parts of the left side and the right side of the hopper box (43), the connecting pipes (73) are connected with valves (71), and the front sides of the discharging pipes (72) are provided with U-shaped grooves (74).

6. A river lining apparatus as claimed in claim 1, wherein: the sliding assembly (2) comprises a cross rod (22) and a first hydraulic cylinder (25); the horizontal pole (22) is located discharging pipe (72) downside, just horizontal pole (22) front side runs through U-shaped recess (74), horizontal pole (22) downside T shape slide bar (21) and T shape logical groove (13) sliding connection, horizontal pole (22) upper portion front side is connected with L shape seat (23), L shape seat (23) rear side with first pneumatic cylinder (25) front end is connected, symmetrical connection has mount pad (24) around first pneumatic cylinder (25) outside.

7. The river lining apparatus of claim 4 wherein: the middle parts of the left side and the right side of the feed box assembly (4) are connected with support assemblies (3), and the support assemblies (3) comprise rollers (31) and L-shaped support plates (32); the two L-shaped support plates (32) are symmetrically distributed in the middle of the left side and the right side of the hopper box (43), the rollers (31) are distributed on the lower side of the L-shaped support plates (32) at equal intervals, the rear sides of the two L-shaped support plates (32) are respectively connected with the front sides of the U-shaped frames (62) left and right, and the front and rear sides of the lower parts of the inner sides of the two L-shaped support plates (32) are respectively connected with the mounting seats (24).

8. The river lining apparatus of claim 4 wherein: the middle part of the upper side of the feed box assembly (4) is connected with a stirring assembly (5), and the stirring assembly (5) comprises a V-shaped stirring rod (51), a rotating shaft (52) and a first motor (53); the first motor (53) is located right above the sealing top cover (42), the rotating shaft (52) penetrates through the middle of the sealing top cover (42) at the lower side of the first motor (53), and the V-shaped stirring rod (51) is connected to the lower side of the periphery of the rotating shaft (52).