CN116876561A - Reinforced gravity type retaining wall earthquake-resistant structure - Google Patents

Abstract

The application belongs to the technical field of retaining walls, in particular to a reinforced gravity type retaining wall earthquake-resistant structure, which comprises a bottom plate, mounting frames arranged on two sides of the surface of the bottom plate, wall plates arranged between the mounting frames, reinforcing ribs obliquely arranged at the included angle between the mounting frames and the bottom plate, and a fixing assembly arranged between the mounting frames and positioned on one side of the wall plates, wherein the reinforcing ribs are welded on the included angle between the mounting frames and the bottom plate; through setting up fixed subassembly, promote the picture peg and drive trapezoidal board A and remove, trapezoidal board A extrudees trapezoidal board B, makes trapezoidal board B promote the wallboard and contradicts the back with the mounting bracket, is connected picture peg and cover board B through external bolt, accomplishes the fixing to the wallboard, makes mounting bracket and wallboard closely laminate, avoids rocking, guarantees the installation steadiness.

Description

Reinforced gravity type retaining wall earthquake-resistant structure

Technical Field

The application belongs to the technical field of retaining walls, and particularly relates to a reinforced gravity type retaining wall earthquake-resistant structure.

Background

The retaining wall is a structure for supporting roadbed filled soil or hillside soil and preventing deformation and instability of the filled soil or soil, and in engineering construction, plates for supporting and reinforcing the pit wall can be also called as the retaining wall, the traditional retaining wall or the concrete is adopted for direct casting, the construction materials are often precast blocks or stones for on-site casting, and a large number of workers are required for on-site long-time construction in the whole construction process of the retaining wall after the retaining wall is assembled, so that the overall construction efficiency is low, and the spliced retaining wall is widely applied to a plurality of fields due to the convenience of later disassembly;

when installing the use to the retaining wall, need insert the wallboard in advance between two support pieces and consolidate through the bolt piece, realize the installation to the retaining wall, but the retaining wallboard is plate structure, and self specification is fixed, when carrying out the installation operation, and support piece's socket bore is fixed, unadjustable, this just leads to inserting the plate in the socket and has the gap between the socket, leads to the plate to easily produce and rocks, and stability is relatively poor, and also easily produces the noise when rocking, influences the operation.

In order to solve the problems, the application provides a reinforced gravity type retaining wall earthquake-resistant structure.

Disclosure of Invention

To solve the problems set forth in the background art. The application provides a reinforced gravity type retaining wall earthquake-resistant structure, which has the characteristics of auxiliary fixation and connection enhancement.

In order to achieve the above purpose, the present application provides the following technical solutions: the reinforced gravity type retaining wall earthquake-resistant structure comprises a bottom plate, mounting frames and wallboards, wherein the mounting frames are mounted on two sides of the surface of the bottom plate, the wallboards are arranged between the mounting frames, reinforcing ribs which are obliquely arranged are welded at the included angle between the mounting frames and the bottom plate, and the reinforced gravity type retaining wall earthquake-resistant structure also comprises fixing components which are mounted between the mounting frames and are positioned on one side of the wallboards;

the fixed subassembly is in including the welding just be the connecting plate that the opposition distributes and the welding is in sleeve board A between the connecting plate, sleeve board A both sides just are located the welding has sleeve board B between the connecting plate, and peg graft in the sleeve board B has the picture peg, the picture peg inserts one side welding in the mounting bracket has trapezoidal board A, trapezoidal board A is kept away from one side welding of picture peg has T shape structural structure's slider to this slider outer slip cap is equipped with trapezoidal board B, trapezoidal board B keep away from one side of trapezoidal board A with the surface conflict of mounting bracket.

As the reinforced gravity type retaining wall shock-resistant structure, preferably, one side of the surface of the sleeve plate A is rotatably connected with a hand wheel, one end of the hand wheel inserted into the sleeve plate A is welded with a gear, the surface of the gear is in meshed connection with oppositely distributed toothed bars, and one side of the toothed bars is fixedly connected with the plugboard at a corresponding position.

As the reinforced gravity type retaining wall earthquake-resistant structure is preferable, a limiting plate with a rectangular structure is welded on the surface of the toothed bar and positioned on one side of the plugboard, and one side of the limiting plate, which is far away from the toothed bar, is connected in a sliding groove formed in the inner wall of the sleeve plate A in a sliding way.

As the reinforced gravity type retaining wall earthquake-resistant structure, the application is preferable, a cavity is formed in the position, corresponding to the trapezoid plate B, of the inner wall of the mounting frame, and the cavity is matched with the trapezoid plate B.

As the reinforced gravity type retaining wall earthquake-resistant structure, preferably, spring rods are fixedly arranged on the surface of the trapezoid plate B and positioned on two sides of the trapezoid plate A, and one end, away from the trapezoid plate B, of each spring rod is fixedly connected with the inner wall of the cavity of the mounting frame.

As a preferable mode of the reinforced gravity type retaining wall earthquake-resistant structure, the reinforced gravity type retaining wall earthquake-resistant structure further comprises a connecting component which is arranged on one side of the surface of the mounting frame far away from the reinforcing ribs;

the connecting assembly comprises a knob and a clamping plate, wherein the knob is rotationally connected in a groove on the surface of the mounting frame, the clamping plate is welded on the inner wall of the mounting frame, the position of the clamping plate corresponds to the position of the knob, the clamping plate is inserted into a socket formed in the position corresponding to the surface of the wallboard, a screw is welded at one end of the knob, the screw is rotationally connected in the clamping plate, the surface of the screw is screwed with a screw sleeve, extrusion blocks A are welded on two sides of the screw sleeve, extrusion blocks B are welded on one side of the screw sleeve, one side of each extrusion block A is welded with a fixing plate, the fixing plate is inserted into a slot formed in the surface of the clamping plate, and one side of each fixing plate, which is far away from each extrusion block B, is clamped in the bayonet formed in the inner wall of the wallboard socket.

As the reinforced gravity type retaining wall earthquake-resistant structure, the application is characterized in that the opposite sides of the extrusion block A and the extrusion block B are of mutually matched inclined structures, and the surfaces of the extrusion block B and the fixing plate are respectively attached to the inside of the slot of the clamping plate.

As the reinforced gravity retaining wall earthquake-resistant structure, the application is characterized in that guide grooves are formed on the two sides of the surface of the fixed plate at positions corresponding to the inner walls of the clamping plate slots, sliding rods are welded in the guide grooves, sliding sleeves are sleeved on the surfaces of the sliding rods, one sides of the sliding sleeves extending out of the surface of the fixed plate are fixedly connected with the clamping plates, stress springs are wound on the surfaces of the sliding rods and positioned on one sides of the sliding sleeves, and the two ends of each stress spring are fixedly connected with the sliding sleeve and the fixed plate respectively.

Compared with the prior art, the application has the beneficial effects that:

through setting up fixed subassembly, promote the picture peg and drive trapezoidal board A and remove, trapezoidal board A extrudees trapezoidal board B, makes trapezoidal board B promote the wallboard and contradicts the back with the mounting bracket, is connected picture peg and cover board B through external bolt, accomplishes the fixing to the wallboard, makes mounting bracket and wallboard closely laminate, avoids rocking, guarantees the installation steadiness.

Through setting up coupling assembling, after the wallboard inserts the mounting bracket, insert the cardboard in the bottom plate to rotatory knob drives the screw rod rotatory, when making swivel nut drive extrusion piece A to extrude extrusion piece B, extrusion piece B drives the fixed plate and inserts in the bottom plate, accomplishes the connection to the bottom plate, makes things convenient for people to further consolidate the operation to the bottom plate.

Drawings

The accompanying drawings are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate the application and together with the embodiments of the application, serve to explain the application. In the drawings:

FIG. 1 is a schematic diagram of the structure of the present application;

FIG. 2 is a schematic view of the structure between a sleeve plate A and a sleeve plate B in the application;

FIG. 3 is a schematic view of the structure of the present application between the mounting bracket, wall panel and the fixing assembly;

FIG. 4 is a schematic view of the structure between the mounting bracket and the trapezoidal plate B in the present application;

FIG. 5 is a schematic view of the structure of the present application between the mounting bracket, wall panel and connection assembly;

FIG. 6 is a schematic view of the structure between the connection assembly and the wall panel of the present application;

FIG. 7 is a schematic view of the structure of the inside of the clamping plate according to the present application;

in the figure:

1. a bottom plate; 2. a mounting frame; 3. reinforcing ribs; 4. a wallboard; 5. a fixing assembly; 6. a connection assembly;

51. a hand wheel; 511. a gear; 512. a limiting plate; 513. a toothed bar; 514. inserting plate; 515. a trapezoid plate A; 516. a trapezoid plate B; 517. a spring rod; 52. a sleeve plate A; 53. a sleeve plate B; 54. a connecting plate;

61. a knob; 62. a clamping plate; 63. a screw sleeve; 64. a screw; 65. extruding a block A; 66. extruding a block B; 67. a fixing plate; 671. a slide bar; 672. a sliding sleeve; 673. stress springs.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

As shown in fig. 1-7;

the utility model provides a reinforced gravity type retaining wall shock-resistant structure, includes bottom plate 1 and installs mounting bracket 2 in bottom plate 1 surface both sides and settle wallboard 4 between mounting bracket 2, and the contained angle department welding of mounting bracket 2 and bottom plate 1 has the strengthening rib 3 that the slope set up.

In this embodiment: the wallboard 4 is inserted between the installation racks 2 and is fixed through bolts, connection is completed, the reinforcing ribs 3 can strengthen support and stress, stability of the installation racks 2 is guaranteed, the retaining wall is of a plate structure, the retaining wall is fixed in specification, the socket caliber of the supporting piece is fixed and is not adjustable when the retaining wall is installed, gaps exist between the plate inserted into the socket and the socket, the plate is easy to shake, stability is poor, noise is easy to generate when the retaining wall shakes, and operation is affected.

The reinforced gravity type retaining wall earthquake-resistant structure further comprises a fixing component 5 which is arranged between the mounting frames 2 and positioned at one side of the wallboard 4;

the fixed assembly 5 comprises connecting plates 54 and sleeve plates A52, wherein the connecting plates 54 are welded between the mounting frames 2 and are oppositely distributed, sleeve plates B53 are welded between the connecting plates 54 and are positioned on two sides of the sleeve plates A52, a plugboard 514 is inserted into the sleeve plates B53, a trapezoid plate A515 is welded on one side, which is inserted into the mounting frames 2, of the plugboard 514, a sliding block of a T-shaped structure is welded on one side, which is far away from the plugboard 514, of the trapezoid plate A515, and a trapezoid plate B516 is sleeved outside the sliding block in a sliding mode, and one side, which is far away from the trapezoid plate A515, of the trapezoid plate B516 is in contact with the surface of the mounting frames 2.

In this embodiment: when pushing picture peg 514 to drive trapezoidal plate A515 and remove, trapezoidal plate A515 extrudees trapezoidal plate B516, makes trapezoidal plate B516 promote wallboard 4 and mounting bracket 2 and contradict the back, is connected picture peg 514 and cover board B53 through outside bolt, accomplishes the fixed to wallboard 4, makes mounting bracket 2 and wallboard 4 closely laminate, avoids rocking, guarantees the installation steadiness.

In an alternative embodiment, a hand wheel 51 is rotatably connected to one side of the surface of the sleeve plate a52, a gear 511 is welded to one end of the hand wheel 51 inserted into the sleeve plate a52, oppositely distributed toothed bars 513 are connected to the surface of the gear 511 in a meshed manner, and one side of the toothed bars 513 is fixedly connected to a plugboard 514 at a corresponding position.

In this embodiment: when the hand wheel 51 is rotated to drive the gear 511 to rotate, the gear 511 is stressed to push the sleeve plate B53 to move through the toothed bar 513, so that people are assisted in fixing the wallboard 4 in a squeezing mode.

In an alternative embodiment, a rectangular limiting plate 512 is welded on the surface of the toothed bar 513 and on one side of the insert plate 514, and one side of the limiting plate 512 away from the toothed bar 513 is slidably connected in a sliding groove formed in the inner wall of the sleeve plate a 52.

In this embodiment: this design is used to ensure stability when the rack 513 moves, ensuring smooth movement of the rack 513.

In an alternative embodiment, a cavity is formed in the inner wall of the mounting frame 2 at a position corresponding to the trapezoidal plate B516, and the cavity is matched with the trapezoidal plate B516.

In this embodiment: this design is used for helping accomodate trapezoidal plate B516, practices thrift area occupied.

In an alternative embodiment, the surface of the trapezoid plate B516 is fixedly provided with spring rods 517 on both sides of the trapezoid plate a515, and one end of the spring rod 517 away from the trapezoid plate B516 is fixedly connected with the inner wall of the cavity of the mounting frame 2.

In this embodiment: when the plugboard 514 drives the trapezoid board A515 to reset, the spring rod 517 is influenced by self shrinkage to drive the trapezoid board B516 to reset, so that gaps between the trapezoid board B516 and the wallboard 4 are enlarged, and people can conveniently take out the wallboard 4.

In combination with the above, the device also comprises a connecting component 6 which is arranged on one side of the surface of the mounting frame 2 far away from the reinforcing rib 3;

the connecting assembly 6 comprises a knob 61 and a clamping plate 62, wherein the knob 61 is rotationally connected in a groove on the surface of the mounting frame 2, the clamping plate 62 is welded on the inner wall of the mounting frame 2, the position of the knob 61 corresponds to the position of the clamping plate 62, the clamping plate 62 is inserted into a socket formed in the position corresponding to the surface of the wallboard 4, one end of the knob 61 inserted into the clamping plate 62 is welded with a screw 64, the screw 64 is rotationally connected in the clamping plate 62, the surface of the screw 64 is screwed with a screw sleeve 63, two sides of the screw sleeve 63 are welded with extrusion blocks A65, one side of the extrusion blocks A65, far from the screw sleeve 63, is welded with extrusion blocks B66, one side of the extrusion blocks B66, far from the extrusion blocks A65, is welded with a fixing plate 67, the fixing plate 67 is inserted into a slot formed in the surface of the clamping plate 62, and one side of the fixing plate 67, far from the extrusion blocks B66, is clamped into a bayonet formed in the inner wall of the socket of the wallboard 4.

In this embodiment: after wallboard 4 inserts mounting bracket 2, insert cardboard 62 in bottom plate 1 to rotatory knob 61 drives screw rod 64 rotation, when making swivel nut 63 drive extrusion piece A65 and extrudeed extrusion piece B66, extrusion piece B66 drives fixed plate 67 and inserts in bottom plate 1, accomplishes the connection to bottom plate 1, makes things convenient for people to further consolidate bottom plate 1.

In an alternative embodiment, the opposite sides of the extrusion block a65 and the extrusion block B66 are in mutually matched inclined structures, and the surfaces of the extrusion block B66 and the fixing plate 67 are respectively fitted into the slots of the clamping plate 62.

In an alternative embodiment, guide grooves are formed on two sides of the surface of the fixing plate 67 at positions corresponding to the inner walls of the slots of the clamping plate 62, sliding rods 671 are welded in the guide grooves, sliding sleeves 672 are sleeved on the surfaces of the sliding rods 671 in a sliding manner, one side, extending out of the surface of the fixing plate 67, of the sliding sleeves 672 is fixedly connected with the clamping plate 62, stress springs 673 are wound on the surface of the sliding rods 671 and on one side of the sliding sleeves 672, and two ends of the stress springs 673 are fixedly connected with the sliding sleeves 672 and the fixing plate 67 respectively.

In this embodiment: when the screw sleeve 63 is driven to reset by the reversing knob 61, the stress spring 673 pulls the fixing plate 67 to reset and is retracted into the clamping plate 62 under the influence of self shrinkage, so that the fixing plate is separated from the wallboard 4, and the clamping plate 62 and the wallboard 4 are assisted to separate.

The working principle and the using flow of the application are as follows: when the hand wheel 51 is rotated to drive the gear 511 to rotate, the gear 511 is stressed to push the sleeve plate B53 to move through the toothed bar 513, the plugboard 514 is pushed to drive the trapezoid plate A515 to move, the trapezoid plate A515 is pushed to extrude the trapezoid plate B516, after the trapezoid plate B516 pushes the wallboard 4 to collide with the mounting frame 2, the plugboard 514 is connected with the sleeve plate B53 through an external bolt, the fixation of the wallboard 4 is completed, the mounting frame 2 is tightly attached to the wallboard 4, shaking is avoided, the installation stability is guaranteed, after the wallboard 4 is inserted into the mounting frame 2, the clamping plate 62 is inserted into the bottom plate 1, the knob 61 is rotated to drive the screw 64 to rotate, the threaded sleeve 63 drives the extrusion block A65 to extrude the extrusion block B66, the extrusion block B66 drives the fixing plate 67 to be inserted into the bottom plate 1, connection of the bottom plate 1 is completed, people can conveniently further reinforce the bottom plate 1, when the threaded sleeve 63 is driven to reset through the reversing knob 61, the stress spring 673 is contracted by the self and the influence to pull the fixing plate 67 to reset and separate the clamping plate 62 from the wallboard 4, and the clamping plate 62 is separated from the wallboard 4, and the clamping plate 62 is assisted in separating operation with the wallboard 4.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present application, and the present application is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present application has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (8)

1. The utility model provides a reinforced gravity type retaining wall antidetonation structure, includes bottom plate (1) and installs mounting bracket (2) and the settling of bottom plate (1) surface both sides are in wallboard (4) between mounting bracket (2), mounting bracket (2) with contained angle department welding of bottom plate (1) has strengthening rib (3) that the slope set up, its characterized in that: the fixing assembly (5) is arranged between the mounting frames (2) and positioned at one side of the wallboard (4);

fixed subassembly (5) are in including the welding just be connecting plate (54) that the opposition distributes between mounting bracket (2) and welding are in bushing A (52) between connecting plate (54), bushing A (52) both sides just are located the welding has bushing B (53) between connecting plate (54), and peg graft in bushing B (53) has picture peg (514), picture peg (514) are inserted one side welding in mounting bracket (2) has trapezoidal plate A (515), trapezoidal plate A (515) are kept away from one side welding of picture peg (514) has T shape structural slider to this slider outer slip cover is equipped with trapezoidal plate B (516), trapezoidal plate B (516) are kept away from one side of trapezoidal plate A (515) with the surface conflict of mounting bracket (2).

2. The reinforced gravity retaining wall seismic structure of claim 1 wherein: a hand wheel (51) is rotatably connected to one side of the surface of the sleeve plate A (52), a gear (511) is welded to one end of the hand wheel (51) inserted into the sleeve plate A (52), oppositely distributed toothed bars (513) are connected to the surface of the gear (511) in a meshed mode, and one side of the toothed bars (513) is fixedly connected with the inserting plate (514) at the corresponding position.

3. The reinforced gravity retaining wall seismic structure of claim 2 wherein: the limiting plate (512) with a rectangular structure is welded on the surface of the toothed bar (513) and positioned on one side of the inserting plate (514), and one side, far away from the toothed bar (513), of the limiting plate (512) is slidably connected in a sliding groove formed in the inner wall of the sleeve plate A (52).

4. The reinforced gravity retaining wall seismic structure of claim 1 wherein: a cavity is formed in the position, corresponding to the trapezoid plate B (516), of the inner wall of the mounting frame (2), and the cavity is matched with the trapezoid plate B (516).

5. The reinforced gravity retaining wall seismic structure of claim 4 wherein: the surface of the trapezoid plate B (516) is fixedly provided with spring rods (517) on two sides of the trapezoid plate A (515), and one end, away from the trapezoid plate B (516), of each spring rod (517) is fixedly connected with the inner wall of the cavity of the mounting frame (2).

6. The reinforced gravity retaining wall seismic structure of claim 1 wherein: the connecting assembly (6) is arranged on one side, far away from the reinforcing rib (3), of the surface of the mounting frame (2);

coupling assembling (6) are in including rotating connection knob (61) in mounting bracket (2) surface recess and welding are in mounting bracket (2) inner wall just cardboard (62) that knob (61) position corresponds, and cardboard (62) are pegged graft in the socket that wallboard (4) surface corresponds position department was seted up, knob (61) inserts one end welding in cardboard (62) has screw rod (64), screw rod (64) rotate and connect in cardboard (62), and the surface spiro union of screw rod (64) has swivel nut (63), the both sides welding of swivel nut (63) have extrusion piece A (65), one side welding that extrusion piece A (65) kept away from swivel nut (63) has extrusion piece B (66), one side welding that extrusion piece A (65) was kept away from has fixed plate (67), fixed plate (67) are pegged graft in the slot that cardboard (62) surface was seted up, and fixed plate (67) are kept away from extrusion piece B's one side is kept away from extrusion piece B (66) is in bayonet socket (4) is seted up in the wallboard.

7. The reinforced gravity retaining wall seismic structure of claim 6 wherein: the side of the extrusion block A (65) and the extrusion block B (66) which are abutted against each other are of mutually matched inclined surface structures, and the surfaces of the extrusion block B (66) and the fixing plate (67) are respectively attached to the inside of the slot of the clamping plate (62).

8. The reinforced gravity retaining wall seismic structure of claim 7 wherein: the fixing device is characterized in that guide grooves are formed in the positions, corresponding to the inner walls of the slots of the clamping plates (62), of the two sides of the surface of the fixing plate (67), sliding rods (671) are welded in the guide grooves, sliding sleeves (672) are sleeved on the surfaces of the sliding rods (671) in a sliding mode, the sliding sleeves (672) extend out of one side of the surface of the fixing plate (67) to be fixedly connected with the clamping plates (62), stress springs (673) are wound on the surface of the sliding rods (671) and located on one side of the sliding sleeves (672), and the two ends of the stress springs (673) are fixedly connected with the sliding sleeves (672) and the fixing plate (67) respectively.