阅读说明：本技术 一种用于隧道施工的模板支撑及其配套的模板 (Formwork support for tunnel construction and matched formwork ) 是由 王平 于 2021-09-26 设计创作，主要内容包括：本申请公开了一种用于隧道施工的模板支撑,配套一种包括顶板和侧板的模板；模板支撑包括顶板支撑组件和侧板支撑组件；顶板支撑组件包括近地支撑块、主支撑杆和滑动块体；近地支撑块为箱体结构,数量为两个,两个近地支撑块相对设置；主支撑杆的数量为两个,主支撑杆的一端可转动定位在近地支撑块上,另一端可转动固定在滑动块体上,两个主支撑杆结构相同且对称设置；滑动块体可拆卸滑动定位在滑动块体导轨上；近地支撑块包括支撑块拉近组件,支撑块拉近组件用于将两个近地支撑块之间的距离拉近；侧板支撑组件包括定位块体、导力杆和支撑小车,用于将顶板和侧板固定在一起并对二者起支撑作用,实现了隧道施工用模板的安全高效构建的技术效果。(The application discloses a formwork support for tunnel construction, which is matched with a formwork comprising a top plate and a side plate; the formwork support comprises a top plate support assembly and a side plate support assembly; the top plate supporting component comprises a near support block, a main support rod and a sliding block body; the two near support blocks are oppositely arranged; the number of the main supporting rods is two, one end of each main supporting rod can be rotatably positioned on the near support block, the other end of each main supporting rod can be rotatably fixed on the sliding block body, and the two main supporting rods are identical in structure and are symmetrically arranged; the sliding block body can be detachably positioned on the sliding block body guide rail in a sliding mode; the near support block comprises a support block drawing-in component, and the support block drawing-in component is used for drawing the distance between the two near support blocks; the side plate supporting component comprises a positioning block body, a force guide rod and a supporting trolley and is used for fixing the top plate and the side plate together and supporting the top plate and the side plate, and the technical effect of safe and efficient construction of the template for tunnel construction is achieved.)

1. A template is characterized in that the template is arched after being assembled;

the template comprises a top plate and two side plates, wherein the number of the top plate is one, and the side plates are directly or indirectly fixed on the top plate when in use;

the top plate comprises a top plate main body, a top plate reinforcing rib, a sliding block guide rail and a top plate supporting wheel;

the top plate main body is an arc-shaped plate, the top plate supporting wheels are positioned on two linear edges of the top plate main body, the number of the top plate supporting wheels is a multiple of 2, and the top plate main body is supported and positioned;

the sliding block guide rail is positioned on the top plate main body and is a straight guide rail, and the axial direction of the sliding block guide rail is the same as that of the top plate main body and is used for supporting and matching with the template;

the side plate comprises a side plate main body, side plate reinforcing ribs and side plate supporting wheels;

the side plate main body is an arc-shaped plate; the side plate supporting wheel is positioned at one end of the side plate main body far away from the top plate;

the side plate supporting wheels play a role in supporting the side plates.

2. A formwork support for tunnel construction, characterized by being fitted with the formwork of claim 1; the formwork support comprises a top plate support assembly and a side plate support assembly;

the top plate supporting assembly comprises a near supporting block, a main supporting rod and a sliding block body;

the two near-support supporting blocks are oppositely arranged, and supporting traveling wheels are arranged below the two near-support supporting blocks;

the number of the main supporting rods is two, one end of each main supporting rod can be rotatably positioned on the near support block, the other end of each main supporting rod can be rotatably fixed on the sliding block body, and the two main supporting rods are identical in structure and are symmetrically arranged;

the sliding block body can be detachably and slidably positioned on the sliding block body guide rail;

the supporting block drawing-in component is used for drawing the distance between the two near-support supporting blocks;

the side plate supporting assembly comprises a positioning block body, a force guide rod and a supporting trolley;

the positioning block bodies are two symmetrically arranged block bodies and are detachably and fixedly connected to the top plate and the side plate;

the supporting trolley comprises a frame body and a travelling wheel, wherein the frame body is a main body of the supporting trolley, and the travelling wheel is positioned below the frame body;

the number of the force guide rods is two, one end of each force guide rod can be rotatably positioned on the positioning block body, and the other end of each force guide rod can be rotatably positioned on the support trolley.

3. The formwork support for tunnel construction of claim 2, further comprising a power assembly and a control unit;

the control unit is used for controlling the coordinated operation of all parts of the template support; the power assembly is used for supplying energy;

the supporting block pulling-in component comprises a pulling rope and a pulling winch;

the pulling winch is positioned on one of the supporting block bodies, and the pulling rope is retracted and released under the control of the control unit;

one end of the pulling rope is fixed on the other supporting block main body, and the other end of the pulling rope is positioned on the pulling winch;

the main support rod comprises a main support rod hinge assembly, a first main support rod and a second main support rod;

the first main supporting rod and the second main supporting rod are rotatably and fixedly connected to the near support block and the sliding block body through the main supporting rod hinge assembly;

the first main supporting rod and the second main supporting rod are identical in structure and are symmetrically arranged.

4. The formwork support for tunnel construction of claim 3, further comprising a formwork lifting assembly;

the template lifting assembly comprises a lifting winch, a lifting rope, a rope body reversing assembly and a rope end hook;

the hoisting winch is positioned on the near support block and used for reeling the hoisting rope under the control of the control unit;

the rope reversing assembly is positioned on the sliding block body and used for guiding the direction of the lifting rope;

the rope hitch is positioned at one end of the lifting rope far away from the lifting winch and used for lifting the side plate;

and auxiliary hoisting holes are positioned on the side plates.

5. The formwork support for tunnel construction of claim 2, further comprising a tension stabilizing assembly;

the tension stabilizing assembly comprises a tension spring, a tension spring fixing assembly, a hook body and a hook arranging ring;

the sliding block body also comprises a hook positioning ring;

the number of the tension springs is two, the two tension springs are symmetrically arranged by taking the sliding block guide rail as a symmetrical line, and the two tension springs are fixed on the top plate through the tension spring fixing component;

the hook body is positioned at one end of the tension spring, which is far away from the tension spring fixing component;

said hook receiving loop positioned on said top plate in spatial proximity to said sliding block guide for receiving said hook body in said template unstructured state;

the hook positioning rings are positioned on the sliding blocks, and the number of the hook positioning rings is one or two, so that the hook positioning rings are used for positioning the hook bodies, and the stability of the template in the construction and disassembly processes is improved;

the top plate supporting assembly also comprises a secondary supporting rod;

the main support rod also comprises a secondary support rod positioning component;

the sliding block body also comprises two secondary sliding blocks, and the two secondary sliding blocks can be detachably positioned on the sliding block body guide rail in a sliding manner;

the secondary supporting rod positioning assembly is positioned on the main supporting rod and used for positioning the secondary supporting rod;

the secondary support rod is rod-shaped and can be stretched and retracted;

the secondary support rod comprises a secondary support rod main body, a secondary support rod telescopic component and a secondary support rod hinge component;

the number of the secondary support rods is two, the two secondary support rods are symmetrically arranged and are respectively a first secondary support rod and a second secondary support rod, and the first secondary support rod and the second secondary support rod are both rotatably and fixedly connected to the secondary sliding block through the secondary support rod hinge assembly;

one end of the secondary support rod, which is far away from the secondary sliding block, can be fixedly connected to the main support rod in a rotating way;

the support rod main body is a telescopic rod.

6. The formwork support for tunnel construction of claim 3, further comprising a stabilizing assembly;

the stabilizing assembly comprises a stabilizing rod body and a telescopic rod body;

the stable rod body and the telescopic rod body are coaxial and form a rod together, and the telescopic rod body can be infinitely stretched and used for adjusting the total length of the stable rod body and the telescopic rod body according to actual conditions;

one end of the rod body formed by the stable rod body and the telescopic rod body is fixed on the near-ground support block, and the other end of the rod body is fixed on the support trolley to play a role in stabilizing.

7. The formwork support for tunnel construction of claim 3, further comprising a failure prevention assembly;

the failure prevention assembly comprises a soft board, a soft board furling assembly and a positioning claw assembly;

the soft board is a soft board, the main body of the soft board is strip-shaped, and one end of the soft board is wound and positioned on the soft board furling assembly in the near support block;

the near support block is of a hollow structure, the main body of the soft board furling assembly is cylindrical, and the soft board furling assembly rotates under the control of the control unit;

the soft plate comprises a plate body groove group and a soft plate guide assembly;

the plate body groove group is a groove arranged on the upper surface of the soft plate and is used for cooperating with the positioning claw assembly to prevent the near support block from suddenly sliding to further cause the top plate to suddenly fall;

the soft board guide assembly is positioned on the side wall of the near support block and is used for guiding the moving track of the soft board;

the positioning claw assembly is positioned on the near support block and plays the role of a pawl in the ratchet mechanism.

8. The formwork support for tunnel construction of claim 7, wherein the panel groove sets comprise a first groove set and a second groove set;

the grooves of the groove groups of the plate body are in a V shape, and the V-shaped grooves are equivalent to the ratchet strips in the ratchet strip mechanism;

the grooves in the first groove group and the second groove group are opposite in direction;

the positioning claw assembly comprises a first claw body, a second claw body, a claw body positioning assembly, an elastic assembly and a claw body rotation driving assembly;

the first claw body and the second claw body are both in a pawl structure and are symmetrically arranged, the first claw body and the second claw body are rotatably and fixedly connected to the near support block through the claw body positioning assembly, the elastic assembly is positioned at the connecting position, and the elastic assembly plays a role in limiting the rotating directions of the first claw body and the second claw body;

the claw body rotation driving assembly is used for driving the first claw body and the second claw body to rotate under the control of the control unit.

9. The formwork support for tunnel construction of claim 6, wherein the stabilizing rod body comprises a stabilizing rod unit and a rod body splicing assembly;

the stable rod body is formed by splicing a plurality of stable rod units through the rod body splicing assembly;

the stabilizing rod units are hollow rods and can be combined with each other;

the rod body splicing assembly comprises a winding drum and a tensioning rope;

the winding drum rotates under the control of the control unit, is positioned on the support trolley or the near support block and is used for winding and unwinding the tensioning rope;

the tensioning rope penetrates through the stable rod unit, and one end of the tensioning rope is fixed on the telescopic rod body;

through the dismouting the mode of firm pole unit can adjust the length of the firm body of rod.

10. The formwork support for tunnel construction of claim 6, further comprising a traffic assembly;

the passing assembly is used for facilitating the passage of personnel through the formwork support;

the passing assembly comprises a pedal platform;

the main body of the pedal platform is trapezoidal, the number of the pedal platform is one or two, the pedal platform is in direct contact with the ground, and a U-shaped groove used for avoiding the stabilizing component is positioned at the bottom of the pedal platform.

Technical Field

The invention relates to the technical field of building formwork supporting devices, in particular to a formwork support for tunnel construction.

Background

In the tunnel lining construction, the template and the template support are important, and the selection of the template and the template support directly influences the construction period.

In the prior art, the construction of tunnel lining usually adopts a conventional trolley; the conventional trolley can meet the construction work of most tunnels, but the benefit maximization cannot be achieved by using the tunnel trolley aiming at the tunnels with smaller diameters and the tunnels with shorter lengths; when the tunnel construction with the unconventional diameter (the tunnel diameter is small) is carried out, the matched tunnel trolley is difficult to rent, the tunnel trolley is generally lined up (the construction period is seriously influenced) or expensive trolley transportation cost is paid, the efficiency of constructing and pouring the tunnel lining by directly using the template support and the template in the prior art is low (the tunnel lining is difficult to disassemble and assemble), the labor intensity of constructors is high, and the safety is low.

Disclosure of Invention

The embodiment of the application solves the technical problems that in the prior art, the template support for tunnel construction is large in labor intensity of construction personnel, low in construction efficiency and poor in safety in the use process, and realizes safe and efficient construction of the template for tunnel construction.

The embodiment of the application provides a template, which is characterized in that the template is arched after being assembled;

the template comprises a top plate and two side plates, wherein the number of the top plate is one, and the side plates are directly or indirectly fixed on the top plate when in use;

the top plate comprises a top plate main body, a top plate reinforcing rib, a sliding block guide rail and a top plate supporting wheel;

the top plate main body is an arc-shaped plate, the top plate supporting wheels are positioned on two linear edges of the top plate main body, the number of the top plate supporting wheels is a multiple of 2, and the top plate main body is supported and positioned;

the sliding block guide rail is positioned on the top plate main body and is a straight guide rail, and the axial direction of the sliding block guide rail is the same as that of the top plate main body and is used for supporting and matching with the template;

the side plate comprises a side plate main body, side plate reinforcing ribs and side plate supporting wheels;

the side plate main body is an arc-shaped plate; the side plate supporting wheel is positioned at one end of the side plate main body far away from the top plate;

the side plate supporting wheels play a role in supporting the side plates.

A template support for tunnel construction is matched with a template; the formwork support comprises a top plate support assembly and a side plate support assembly;

the top plate supporting assembly comprises a near supporting block, a main supporting rod and a sliding block body;

the two near-support supporting blocks are oppositely arranged, and supporting traveling wheels are arranged below the two near-support supporting blocks;

the number of the main supporting rods is two, one end of each main supporting rod can be rotatably positioned on the near support block, the other end of each main supporting rod can be rotatably fixed on the sliding block body, and the two main supporting rods are identical in structure and are symmetrically arranged;

the sliding block body can be detachably and slidably positioned on the sliding block body guide rail;

the supporting block drawing-in component is used for drawing the distance between the two near-support supporting blocks;

the side plate supporting assembly comprises a positioning block body, a force guide rod and a supporting trolley;

the positioning block bodies are two symmetrically arranged block bodies and are detachably and fixedly connected to the top plate and the side plate;

the supporting trolley comprises a frame body and a travelling wheel, wherein the frame body is a main body of the supporting trolley, and the travelling wheel is positioned below the frame body;

the number of the force guide rods is two, one end of each force guide rod can be rotatably positioned on the positioning block body, and the other end of each force guide rod can be rotatably positioned on the support trolley.

Preferably, the device also comprises a power assembly and a control unit;

the control unit is used for controlling the coordinated operation of all parts of the template support; the power assembly is used for supplying energy;

the supporting block pulling-in component comprises a pulling rope and a pulling winch;

the pulling winch is positioned on one of the supporting block bodies, and the pulling rope is retracted and released under the control of the control unit;

one end of the pulling rope is fixed on the other supporting block main body, and the other end of the pulling rope is positioned on the pulling winch;

the main support rod comprises a main support rod hinge assembly, a first main support rod and a second main support rod;

the first main supporting rod and the second main supporting rod are rotatably and fixedly connected to the near support block and the sliding block body through the main supporting rod hinge assembly;

the first main supporting rod and the second main supporting rod are identical in structure and are symmetrically arranged.

Preferably, the device further comprises a template lifting assembly;

the template lifting assembly comprises a lifting winch, a lifting rope, a rope body reversing assembly and a rope end hook;

the hoisting winch is positioned on the near support block and used for reeling the hoisting rope under the control of the control unit;

the rope reversing assembly is positioned on the sliding block body and used for guiding the direction of the lifting rope;

the rope hitch is positioned at one end of the lifting rope far away from the lifting winch and used for lifting the side plate;

and auxiliary hoisting holes are positioned on the side plates.

Preferably, the device also comprises a tension stabilizing component;

the tension stabilizing assembly comprises a tension spring, a tension spring fixing assembly, a hook body and a hook arranging ring;

the sliding block body also comprises a hook positioning ring;

the number of the tension springs is two, the two tension springs are symmetrically arranged by taking the sliding block guide rail as a symmetrical line, and the two tension springs are fixed on the top plate through the tension spring fixing component;

the hook body is positioned at one end of the tension spring, which is far away from the tension spring fixing component;

said hook receiving loop positioned on said top plate in spatial proximity to said sliding block guide for receiving said hook body in said template unstructured state;

the hook positioning rings are positioned on the sliding blocks, and the number of the hook positioning rings is one or two, so that the hook positioning rings are used for positioning the hook bodies, and the stability of the template in the construction and disassembly processes is improved;

the top plate supporting assembly also comprises a secondary supporting rod;

the main support rod also comprises a secondary support rod positioning component;

the sliding block body also comprises two secondary sliding blocks, and the two secondary sliding blocks can be detachably positioned on the sliding block body guide rail in a sliding manner;

the secondary supporting rod positioning assembly is positioned on the main supporting rod and used for positioning the secondary supporting rod;

the secondary support rod is rod-shaped and can be stretched and retracted;

the secondary support rod comprises a secondary support rod main body, a secondary support rod telescopic component and a secondary support rod hinge component;

the number of the secondary support rods is two, the two secondary support rods are symmetrically arranged and are respectively a first secondary support rod and a second secondary support rod, and the first secondary support rod and the second secondary support rod are both rotatably and fixedly connected to the secondary sliding block through the secondary support rod hinge assembly;

one end of the secondary support rod, which is far away from the secondary sliding block, can be fixedly connected to the main support rod in a rotating way;

the support rod main body is a telescopic rod.

Preferably, a stabilizing component is also included;

the stabilizing assembly comprises a stabilizing rod body and a telescopic rod body;

the stable rod body and the telescopic rod body are coaxial and form a rod together, and the telescopic rod body can be infinitely stretched and used for adjusting the total length of the stable rod body and the telescopic rod body according to actual conditions;

one end of the rod body formed by the stable rod body and the telescopic rod body is fixed on the near-ground support block, and the other end of the rod body is fixed on the support trolley to play a role in stabilizing.

Preferably, the device also comprises an anti-failure component;

the failure prevention assembly comprises a soft board, a soft board furling assembly and a positioning claw assembly;

the soft board is a soft board, the main body of the soft board is strip-shaped, and one end of the soft board is wound and positioned on the soft board furling assembly in the near support block;

the near support block is of a hollow structure, the main body of the soft board furling assembly is cylindrical, and the soft board furling assembly rotates under the control of the control unit;

the soft plate comprises a plate body groove group and a soft plate guide assembly;

the plate body groove group is a groove arranged on the upper surface of the soft plate and is used for cooperating with the positioning claw assembly to prevent the near support block from suddenly sliding to further cause the top plate to suddenly fall;

the soft board guide assembly is positioned on the side wall of the near support block and is used for guiding the moving track of the soft board;

the positioning claw assembly is positioned on the near support block and plays the role of a pawl in the ratchet mechanism.

Preferably, the plate groove group comprises a first groove group and a second groove group;

the grooves of the groove groups of the plate body are in a V shape, and the V-shaped grooves are equivalent to the ratchet strips in the ratchet strip mechanism;

the grooves in the first groove group and the second groove group are opposite in direction;

the positioning claw assembly comprises a first claw body, a second claw body, a claw body positioning assembly, an elastic assembly and a claw body rotation driving assembly;

the first claw body and the second claw body are both in a pawl structure and are symmetrically arranged, the first claw body and the second claw body are rotatably and fixedly connected to the near support block through the claw body positioning assembly, the elastic assembly is positioned at the connecting position, and the elastic assembly plays a role in limiting the rotating directions of the first claw body and the second claw body;

the claw body rotation driving assembly is used for driving the first claw body and the second claw body to rotate under the control of the control unit.

Further, the stabilizing rod body comprises a stabilizing rod unit and a rod body splicing assembly;

the stable rod body is formed by splicing a plurality of stable rod units through the rod body splicing assembly;

the stabilizing rod units are hollow rods and can be combined with each other;

the rod body splicing assembly comprises a winding drum and a tensioning rope;

the winding drum rotates under the control of the control unit, is positioned on the support trolley or the near support block and is used for winding and unwinding the tensioning rope;

the tensioning rope penetrates through the stable rod unit, and one end of the tensioning rope is fixed on the telescopic rod body;

through the dismouting the mode of firm pole unit can adjust the length of the firm body of rod.

Preferably, the device further comprises a passing component;

the passing assembly is used for facilitating the passage of personnel through the formwork support;

the passing assembly comprises a pedal platform;

the main body of the pedal platform is trapezoidal, the number of the pedal platform is one or two, the pedal platform is in direct contact with the ground, and a U-shaped groove used for avoiding the stabilizing component is positioned at the bottom of the pedal platform.

One or more technical solutions provided in the embodiments of the present application have at least the following technical effects or advantages:

by providing the formwork support, the formwork support comprises a top plate support assembly and a side plate support assembly, the main body of the top plate support assembly is triangular, the top plate of the formwork is supported by changing the length of the ground-near side of the triangle, and the side plate support is used for combining the top plate of the formwork and the side plate of the formwork and supporting and stabilizing the formwork; the technical problems that in the prior art, the construction personnel of the formwork support for tunnel construction have high labor intensity, low construction efficiency and poor safety in the use process are effectively solved, and the safe and efficient construction of the formwork for tunnel construction is further realized.

Drawings

FIG. 1 is a schematic structural view of a form and form support of the present invention;

FIG. 2 is a schematic structural view of a formwork support for tunnel construction according to the present invention;

FIG. 3 is a schematic view showing the positional relationship between the formwork support and the formwork for tunnel construction according to the present invention;

FIG. 4 is a schematic structural view of the top plate of the form of the present invention;

FIG. 5 is a schematic view of the construction of the side panel of the form of the present invention;

FIG. 6 is a schematic view of the construction of the roof support assembly of the present invention;

FIG. 7 is a schematic view of the anti-defeat assembly of the present invention;

FIG. 8 is a schematic structural view of the flexible board of the present invention;

FIG. 9 is a schematic view of the construction of the stabilizing assembly of the present invention;

FIG. 10 is a schematic view of a stable rod according to the present invention;

FIG. 11 is a schematic view of the positioning pawl assembly of the present invention;

fig. 12 is a sectional view of the flexible board of the present invention.

In the figure:

the lifting device comprises a template 100, a top plate 110, a top plate main body 111, a top plate reinforcing rib 112, a tension stabilizing assembly 113, a tension spring 114, a tension spring fixing assembly 115, a hook body 116, a hook arranging ring 117, a top plate supporting wheel 118, a sliding block guide rail 119, a side plate 120, a side plate main body 121, a side plate reinforcing rib 122, a side plate supporting wheel 123 and an auxiliary lifting hole 124;

a top plate supporting assembly 200, a proximal supporting block 210, a supporting block main body 211, a supporting traveling wheel 212, a main supporting rod seating groove 216, a supporting block pulling-up assembly 217, a pulling rope 218, a pulling winch 219, a main supporting rod 220, a main supporting rod hinge assembly 221, a first main supporting rod 222, a second main supporting rod 223, a sub supporting rod positioning assembly 224, a main supporting rod telescopic assembly 225, a sub supporting rod 230, a sub supporting rod main body 231, a sub supporting rod telescopic assembly 232, a sub supporting rod hinge assembly 233, a first sub supporting rod 234, a second sub supporting rod 235, a sliding block 240, a main sliding block 241, a hook positioning ring 241-1, a roller 241-2 and a sub sliding block 242;

the side plate support assembly 300, a positioning block body 310, a first positioning block body 311, a second positioning block body 312, a force guide rod 320, a first force guide rod 321, a second force guide rod 322, a force guide rod abutting part 323, a support trolley 330, a frame body 331, a traveling wheel 332 and a force guide rod positioning assembly 333;

a stabilizing assembly 400, a stabilizing rod body 410, a stabilizing rod unit 411, a rod body splicing assembly 412, a winding drum 413, a tensioning rope 414 and a telescopic rod body 420;

template lifting assembly 500, lifting winch 510, lifting rope 520, rope reversing assembly 530 and rope hitch 540;

the anti-failure assembly 600, the soft plate 610, the plate body groove group 611, the first groove group 612, the second groove group 613, the soft plate guide assembly 614, the soft plate furling assembly 620, the wear-resistant assembly 630, the V-shaped metal plate 631, the positioning claw assembly 640, the first claw body 641, the second claw body 642, the claw body positioning assembly 643, the elastic assembly 644, the claw body rotation driving assembly 645 and the cam 646;

traffic assembly 700, foot rest 710, U-shaped channel 711.

Detailed Description

In order to facilitate an understanding of the present invention, the present application will now be described more fully with reference to the accompanying drawings; the preferred embodiments of the present invention are illustrated in the accompanying drawings, but the invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete.

It is noted that the terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs; the terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention; as used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Please refer to fig. 1, which is a schematic structural diagram of a template and a template support according to the present invention; the formwork support for tunnel construction of the present application includes a roof support assembly 200 and a side panel support assembly 300; the present application provides a formwork support, which comprises a top plate support assembly 200 and a side plate support assembly 300, wherein the main body of the top plate support assembly 200 is triangular, the top plate 110 of the formwork 100 is supported by changing the length of the ground-near side of the triangle, and the side plate support assembly 300 is used for combining the top plate 110 of the formwork 100 and the side plate 120 of the formwork 100 and supporting and stabilizing the formwork 100.

Example one

As shown in fig. 1, the formwork support for tunnel construction of the present application is matched with a formwork 100; the template 100 is arched after being assembled; further, as shown in fig. 1 and 3, the form panel 100 includes a top panel 110 and side panels 120; the number of the top plates 110 is one; the number of the side plates 120 is two, and the side plates are directly or indirectly fixed on the top plate 110 when in use.

Further, as shown in fig. 4, the top plate 110 includes a top plate main body 111, a top plate reinforcing rib 112, a sliding block guide 119, and a top plate supporting wheel 118; the top plate main body 111 is an arc-shaped plate; the top plate reinforcing ribs 112 are positioned on the top plate main body 111 and used for preventing the top plate main body 111 from deforming in the using process; the sliding block guide 119 is positioned on the top plate main body 111 and is a straight guide, the axial direction of the sliding block guide 119 is the same as the axial direction of the top plate main body 111, and the sliding block 240 is used for positioning the top plate supporting assembly 200; the top plate supporting wheels 118 are positioned on two straight edges of the top plate main body 111, the number of the top plate supporting wheels is a multiple of 2, and the top plate supporting wheels are preferably universal wheels and play a role in supporting and positioning the top plate main body 111.

Preferably, the sliding block guide 119 is fixed to the top plate body 111 or integrally formed with the top plate body 111.

Further, as shown in fig. 5, the side plate 120 includes a side plate main body 121, a side plate reinforcing rib 122 and a side plate supporting wheel 123; the side plate main body 121 is an arc-shaped plate; the side plate reinforcing ribs 122 are positioned on the side plate main body 121; the side plate supporting wheel 123 is positioned at one end of the side plate main body 121 far away from the top plate 110; the side plate supporting wheels 123 are preferably universal wheels, and the number of the side plate supporting wheels is preferably a plurality, and the side plate supporting wheels play a role in supporting the side plate 120.

Further, the top plate 110 and the side plate 120 are both provided with a demoulding hole and a grouting hole.

As shown in fig. 2, the formwork support includes a top plate support assembly 200 and a side plate support assembly 300; the top plate supporting assembly 200 serves to support the top plate 110, and the side plate supporting assembly 300 serves to fix and support the top plate 110 and the side plate 120 together.

Further, the top plate support assembly 200 includes a proximal support block 210, a main support rod 220, and a sliding block 240; the near support block 210 is a box structure, directly contacts with the ground, and plays a role of supporting the main support rod 220; the number of the near-support blocks 210 is two, the two near-support blocks 210 are arranged oppositely, the lower parts of the two near-support blocks are provided with support traveling wheels 212, the support traveling wheels 212 can be retracted into the near-support blocks 210, and a support wheel rotation driving component is positioned in the near-support blocks 210; the number of the main supporting rods 220 is two, the main body is a rod, one end of the main supporting rod 220 can be rotatably positioned on the near supporting block 210, the other end of the main supporting rod 220 can be rotatably fixed on the sliding block 240, each main supporting rod 220 corresponds to one near supporting block 210, and the two main supporting rods 220 have the same structure and are symmetrically arranged; the sliding block 240 is detachably and slidably positioned on the sliding block guide rail 119; the proximal support block 210 includes a support block drawing member 217, and the support block drawing member 217 is used to draw the distance between the two proximal support blocks 210 to lift the top plate 110.

Further, the formwork support further comprises a power assembly and a control unit; the proximal support block 210 comprises a support block body 211; a main supporting rod placing groove 216 is positioned on the supporting block main body 211; the main supporting bar seating groove 216 is positioned on the upper surface of the supporting block body 211, and is a straight groove, the main supporting bar 220 is positioned in the main supporting bar seating groove 216, and the main supporting bar 220 can rotate 180 degrees. Further, the supporting traveling wheel 212 comprises a traveling wheel main body and a traveling wheel telescopic assembly, and the traveling wheel telescopic assembly is preferably an (electric) telescopic rod; the travel wheel telescopic assembly is controlled by the control unit to extend and retract so as to extend the travel wheel main body out of the supporting block main body 211.

The control unit is used for controlling the coordinated operation of all parts of the template support, preferably a programmable logic controller or a switch set, and the power assembly is used for supplying power.

Preferably, the control unit comprises a remote control assembly.

Further, the structure of the supporting block pulling-in component 217 is shown in fig. 6, and comprises a pulling rope 218 and a pulling winch 219; the pulling winch 219 is positioned on one of the supporting block bodies 211, and the pulling rope 218 is wound and unwound under the control of the control unit; one end of the pulling rope 218 is fixed to the other supporting block body 211, and the other end is positioned on the pulling winch 219.

Further, the main support rod 220 includes a main support rod hinge assembly 221, a first main support rod 222 and a second main support rod 223; the first main support rod 222 and the second main support rod 223 are rotatably and fixedly connected to the near support block 210 and the sliding block 240 through the main support rod hinge assembly 221; the first main supporting rod 222 and the second main supporting rod 223 are identical in structure and are symmetrically arranged.

Preferably, in order to facilitate the transportation and installation of the main support bar 220 and to be suitable for different formworks 100, the main support bar 220 further comprises a main support bar telescoping assembly 225, and the main support bar 220 can be telescoped under the control of the control unit.

Further, the sliding block 240 includes a main sliding block 241, the main sliding block 241 is slidably located on the sliding block guide rail 119, a sliding block locking assembly is located at a position of the sliding block guide rail 119 near the middle portion, and the sliding block locking assembly operates under the control of the control unit, so as to fix the sliding block 240 on the top plate 110.

Preferably, in order to reduce friction of the sliding block 240 when the sliding block guide 119 slides, a roller 241-2 is positioned on the sliding block 240.

Preferably, the sliding block locking assembly is a pin and pin hole combination.

The side plate support assembly 300 is shown in fig. 2 and comprises a positioning block 310, a force guide rod 320 and a support trolley 330; the positioning block 310 is detachably and fixedly connected to the top plate 110 and the side plate 120, and plays a role in fixing the top plate 110 and the side plate 120 together, and the fixing mode is preferably bolt connection; the number of the positioning block bodies 310 is two, and the two positioning block bodies are symmetrically arranged and are respectively a first positioning block body 311 and a second positioning block body 312; the supporting trolley 330 is a frame structure, and includes a frame 331, a traveling wheel 332 and a force-guiding rod positioning component 333; the frame body 331 is a main body of the support trolley 330; the traveling wheels 332 are positioned below the frame 331, and preferably have the same structure as the supporting traveling wheels 212; the force guide rod positioning component 333 is positioned above the frame 331 for positioning the force guide rod 320; the number of the force guide rods 320 is two, one end of each force guide rod is rotatably positioned on the positioning block 310, and the other end of each force guide rod is rotatably positioned on the support trolley 330.

Further, the force guide rod 320 includes a first force guide rod 321 and a second force guide rod 322; the force guide rod 320 is provided with a force guide rod abutting part 323, the force guide rod abutting part 323 is preferably a plane, when the force guide rod 320 is in a vertical state, the force guide rod abutting part 323 abuts against the positioning block 310 and/or the support trolley 330, and the force guide rod abutting part 323 plays a role in stabilizing the side plate support assembly 300.

Preferably, in order to facilitate the construction of the template of the present application and reduce labor intensity, the template support further comprises a template lift assembly 500; as shown in fig. 2 and 6, the form lifting assembly 500 includes a lifting hoist 510, a lifting rope 520, a rope reversing assembly 530, and a rope hitch 540; the hoisting winch 510 is positioned on the near support block 210 for winding up the hoisting rope 520 under the control of the control unit; the rope diverting assembly 530 is positioned on the sliding block 240 to guide the direction of the hoisting rope 520, and preferably has a fixed pulley structure; the rope hitch 540 is positioned at an end of the hoist rope 520 remote from the hoist 510 for lifting the side panel 120; as shown in fig. 5, the side plate 120 is provided with an auxiliary lifting hole 124.

In order to reduce the risk during the construction of the template, the safety is improved; preferably, the formwork support assembly 200 further comprises a tension stabilizing assembly 113; further, as shown in fig. 2 and 4, the tension stabilizing assembly 113 includes a tension spring 114, a tension spring fixing assembly 115, a hook body 116 and a hook setting ring 117; the sliding block 240 further comprises a hook positioning ring 241-1; the number of the tension springs 114 is two, the two tension springs 114 are symmetrically arranged by taking the sliding block guide rail 119 as a symmetry line, and are fixed on the top plate 110 through the tension spring fixing component 115; the hook body 116 is positioned at one end of the tension spring 114 far away from the tension spring fixing component 115; said hook receiving loop 117 is positioned on said top plate 110 in spatial proximity to said sliding block guide 119 for receiving said hook body 116 in an unstructured state of said form 100; the hook positioning rings 241-1 are positioned on the main sliding block 241, and the number of the hook positioning rings is one or two, and the hook positioning rings are used for positioning the hook bodies 116 to improve the stability of the template 100 in the process of construction and disassembly.

In order to further reduce the risk of the template construction and improve the safety; preferably, the roof support assembly 200 further includes a secondary support bar 230; the primary support pole 220 further includes a secondary support pole positioning assembly 224; the sliding block 240 further comprises two sub-sliding blocks 242, and the two sub-sliding blocks 242 are detachably, slidably and fixedly positioned on the sliding block guide rail 119; the secondary support rod positioning assembly 224 is disposed on the primary support rod 220 for positioning the secondary support rod 230; the secondary support rod 230 is rod-shaped and can be extended and retracted; the secondary support rod 230 comprises a secondary support rod main body 231, a secondary support rod telescopic component 232 and a secondary support rod hinge component 233; the number of the secondary support rods 230 is two, and the two secondary support rods are symmetrically arranged and respectively comprise a first secondary support rod 234 and a second secondary support rod 235, and the two secondary support rods are rotatably and fixedly connected to the secondary sliding block 242 through the secondary support rod hinge assembly 233; one end of the secondary support rod 230 away from the secondary sliding block 242 is rotatably and fixedly connected to the primary support rod 220; the support rod main body 231 is a telescopic rod; the secondary support rod extension assembly 232 is positioned inside the support rod body 231, preferably by a compression spring.

The template support of the present application, when building the template 100:

1. in the initial state, the distance between the two near support blocks 210 is drawn to be longest; the top plate 110 is placed on the ground in an arch shape (in this case, the height of the main sliding block 241 is lower than that of the sliding block guide 119);

2. shortening the distance between the two proximal support blocks 210 by the support block retraction assembly 217 until the sliding block 240 can slide into the sliding block guide 119;

3. after that, the near support block 210 is driven to travel on the ground, the sliding block 240 is made to slide into the sliding block guide 119 and the main sliding block 241 reaches the position of the sliding block guide 119 close to the middle; removing the hook body 116 from the hook mounting ring 117 and hanging the hook body on the hook positioning ring 241-1;

4. operating the support block retraction assembly 217 to shorten the distance between the two proximal support blocks 210 (operating the support traveling wheels 212 and the main support rod retraction assembly 225 in coordination) to lift the top plate 110 to a target position (to fix the position of the top plate 110);

5. the operator controls the hoisting winch 510 to operate, and the rope end hook 540 is hung on the auxiliary hoisting hole 124; controlling the lifting winch 510 to operate to lift the side plate 120; pushing the side plate 120 to the approximate mounting position of the side plate 120;

6. pushing the side plate support assembly 300 under the top plate 110, rotating the force guide rod 320, and fixing the positioning block 310 on the side plate 120;

7. pushing the support trolley 330 to make the force guide rod 320 continue to rotate so as to force the positioning block 310 to rise;

8. fixing the positioning block 310 on the top plate 110, and pushing the support cart 330 to keep the force guide bar 320 vertical, thereby completing the construction of the template 100 of the present application.

When formwork support of this application dismantles template 100:

firstly, detaching the positioning block 310 from the top plate 110, pushing the support trolley 330 to rotate the force guide rod 320, and then demoulding; after demolding, the side plates 120 are directly pushed away together with the supporting trolley 330; and then controlling the support block drawing-in assembly 217 to operate, extending the distance between the two near support blocks 210, and reducing the height of the top plate 110 to realize the removal of the formwork 100.

In order to improve the applicability of the formwork support of the present application (one formwork support can match with various types of formworks 100), it is preferable that the force guide bar 320 further comprises a force guide bar telescoping assembly, which can be controlled to telescope.

The technical scheme in the embodiment of the application at least has the following technical effects or advantages:

the technical problems that in the prior art, the construction personnel of the formwork support for tunnel construction have high labor intensity, low construction efficiency and poor safety in the use process are solved, and the safe and efficient construction of the formwork for tunnel construction is realized.

Example two

In order to further improve the stability of the formwork support of the present application, the present application embodiment adds a stabilizing assembly 400 between the near-ground support block 210 and the support trolley 330 on the basis of the above embodiments;

further, as shown in fig. 2, 9 and 10, the stabilizing assembly 400 includes a stabilizing rod 410 and a telescopic rod 420; the stabilizing rod body 410 and the telescopic rod body 420 are coaxial and form a rod together, and the telescopic rod body 420 can stretch in a stepless manner and is used for adjusting the total length of the stabilizing rod body 410 and the telescopic rod body 420 according to actual conditions; one end of the rod body formed by the stable rod body 410 and the telescopic rod body 420 is fixed on the near-ground support block 210, and the other end is fixed on the support trolley 330, so as to play a role of stabilization.

Preferably, as shown in fig. 9 and 10, the stabilizing rod body 410 includes a stabilizing rod unit 411 and a rod body splicing assembly 412; the stable rod body 410 is formed by splicing a plurality of stable rod units 411 through the rod body splicing assembly 412; the fixing rod units 411 are hollow rods and can be combined with each other; the rod splicing assembly 412 comprises a winding drum 413 and a tensioning rope 414; the winding drum 413 rotates under the control of the control unit, is positioned on the support trolley 330 or the near support block 210, and is used for winding and unwinding the tensioning rope 414; the tightening rope 414 passes through the fixing rod unit 411 and has one end fixed to the telescopic rod body 420; the embodiment of the present application can adjust the length of the stabilizing rod body 410 by disassembling and assembling the stabilizing rod unit 411; the stable splicing of the stable rod unit 411 is achieved by winding the tension cord 414 through the winding drum 413.

Considering that the stability assembly 400 is configured to obstruct the passage of a worker, it is preferable that the formwork support further includes a passage assembly 700, the passage assembly 700 being configured to facilitate the passage of a worker through the formwork support; further, as shown in fig. 1 and 3, the passing assembly 700 includes a foot platform 710; the stepping platform 710 has a trapezoidal main body, one or two, which is in direct contact with the ground, and a U-shaped groove 711 for avoiding the stabilizing member 400 is positioned at the bottom of the stepping platform 710.

In order to further improve the stability of the formwork support, preferably, the anti-failure component 600 is additionally arranged on the basis of the scheme; as shown in fig. 8, 11 and 12, the defeat prevention assembly 600 includes a soft board 610, a soft board furling assembly 620 and a positioning pawl assembly 640; as shown in fig. 7 and 8, the soft board 610 is a soft board, and has a strip-shaped main body, and one end of the soft board is wound around the soft board furling assembly 620 positioned inside the proximal support block 210; the near support block 210 is a hollow structure, the main body of the soft board furling assembly 620 is cylindrical, and the soft board furling assembly rotates under the control of the control unit; the soft board 610 is preferably made of rubber; the soft plate 610 comprises a plate body groove group 611 and a soft plate guide assembly 614; the plate body groove group 611 is a groove formed on the upper surface of the soft plate 610, and is used for cooperating with the positioning pawl assembly 640 to prevent the near support block 210 from suddenly sliding and further causing the top plate 110 to suddenly drop; the soft board guide assembly 614 is positioned on the sidewall of the proximal support block 210 for guiding the moving track of the soft board 610; the positioning pawl assembly 640 is positioned on the proximal support block 210 to act as a pawl in a ratchet mechanism.

Preferably, the flexible board guide assembly 614 is a cylindrical protrusion.

Further, as shown in fig. 8, the plate groove group 611 includes a first groove group 612 and a second groove group 613; the grooves of the plate groove group 611 are all in a V shape, and the V-shaped grooves are equivalent to the ratchets in the ratchets mechanism; the grooves in the first groove group 612 and the second groove group 613 are in opposite directions; the positioning pawl assembly 640 is shown in fig. 11, and includes a first pawl body 641, a second pawl body 642, a pawl positioning assembly 643, an elastic assembly 644, and a pawl rotation driving assembly 645; the first claw body 641 and the second claw body 642 are both of a pawl structure, and are symmetrically arranged, and are rotatably and fixedly connected to the proximal support block 210 through the claw body positioning assembly 643, an elastic assembly 644 is positioned at the connecting position, and the elastic assembly 644 plays a role in limiting the rotating direction of the first claw body 641 and the second claw body 642; the claw body rotation driving assembly 645 is configured to drive the first claw body 641 and the second claw body 642 to rotate under the control of the control unit.

Preferably, the pawl body rotation drive assembly 645 includes a cam 646 and a cam rotation drive assembly; the first claw body 641 and the second claw body 642 are abutted against the cam 646, and the first claw body 641 or the second claw body 642 is rotated (inserted into the plate body groove group 611 or separated from the plate body groove group 611) when the cam 646 is rotated.

Preferably, in order to reduce the wear of the plate body groove group 611 on the soft plate 610 during use, the anti-failure assembly 600 further comprises a V-shaped metal plate 631; the V-shaped metal plate 631 is positioned on the plate body groove group 611 and is used for directly contacting with the first claw body 641 or the second claw body 642, so as to reduce abrasion.

Preferably, for cost saving, the rotating components inside the near support block 210 can be driven by the same motor.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.