CN216194502U - Novel assembled hydraulic steel gate - Google Patents

Abstract

The utility model relates to the technical field of hydraulic engineering, in particular to a novel assembly type hydraulic steel gate which comprises a panel, wherein the edge part of the inner side of the panel is symmetrically detachably connected with edge beam assemblies, a plurality of longitudinal beams are arranged between the two edge beam assemblies, the edge parts of the longitudinal beams are detachably connected with the inner side of the panel, the end parts of the adjacent longitudinal beams are detachably connected with a first connecting piece, the side walls of the adjacent longitudinal beams are detachably connected with a plurality of cross beams, the end parts of the cross beams are inserted into the inner side of the panel, the edge beam assemblies, the longitudinal beams and the side walls of the cross beams are jointly inserted with an inserting assembly, a support arm is detachably connected between the two outermost longitudinal beams, and the side walls of the support arm are matched and connected with the side walls of the cross beams.

Description

Novel assembled hydraulic steel gate

Technical Field

The utility model relates to the technical field of hydraulic engineering, in particular to a novel assembled hydraulic steel gate.

Background

The hydraulic steel gate is an important flow regulating device in water conservancy and hydropower engineering, and especially plays an important role in aspects of flood control, power generation, shipping, water resource allocation and the like. The safety and stability of the hydraulic steel gate determine the safety and benefit of the whole hydraulic and hydroelectric engineering and the safety of the lives and properties of the downstream people to a great extent, so that the safety and stability of the hydraulic steel gate are very important and necessary.

The hydraulic steel gate commonly used in hydraulic and hydroelectric engineering mainly comprises an arc steel gate, a plane steel gate and a herringbone gate. At present, different gate types are formed by plates, beams and columns (arc steel gates), and the plates and the beams (plane steel gates and herringbone gates) are connected through welding and bolts. Welding is the most common connecting method applied to hydraulic steel structures, and has the main advantages that the section of a steel member is not weakened, and splicing plates are not needed; the welded structure has simple structure, convenient manufacture and processing and good sealing performance; the main defects are that high temperature is generated locally during welding, the material performance of a heat affected zone is reduced and the material is not shrunk uniformly, the residual stress and the residual deformation of a welding structure are easy to cause, the welding quality is not easy to check, cracks are prone to being generated, and the tiny cracks often cause brittle failure or fatigue failure in the working process of a hydraulic steel gate. The bolt connection has the advantages of simple operation, convenient disassembly and easy inspection and guarantee of connection quality, but has the obvious defects that holes need to be drilled in the connecting components, the drilled holes damage the integrity of the components, stress concentration is easy to cause, and finally the fatigue failure of the components is caused. In view of the above problems in the prior art, a need exists for a novel fabricated hydraulic steel gate and a design method thereof, which avoid welding and bolting.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a novel assembly type hydraulic steel gate, which aims to solve the problems and achieve the purposes of avoiding welding and bolt connection during gate assembly.

In order to achieve the purpose, the utility model provides the following scheme: the utility model provides a novel assembled hydraulic steel gate, includes the panel, panel inboard limit portion symmetry can be dismantled and be connected with the boundary beam subassembly, two be provided with a plurality of longerons between the boundary beam subassembly, the longeron limit portion with the panel inboard can be dismantled and connect, adjacent the longeron tip can be dismantled and be connected with first connecting piece, and is adjacent the longeron lateral wall can be dismantled and be connected with a plurality of crossbeams, the crossbeam tip with panel inboard is pegged graft, the boundary beam subassembly the longeron with the crossbeam lateral wall is pegged graft jointly and is had grafting subassembly, is located two in the outside can dismantle between the longeron and be connected with the support arm, the support arm lateral wall with the cooperation of crossbeam lateral wall is connected.

Preferably, a plurality of first grooves are formed in the inner side wall of the panel, the cross section of each first groove is of an isosceles trapezoid structure, and the edge beam assembly and the longitudinal beam are detachably connected with the panel through the first grooves; a plurality of inserting grooves are formed in the middle of the inner side wall of the panel, the inserting grooves are located between the adjacent first grooves, and the cross beam is inserted into the panel through the inserting grooves.

Preferably, the boundary beam assembly comprises symmetrically arranged boundary beams, a first protrusion is fixedly connected to the outer side portion of each boundary beam, the first protrusion is matched with the first groove, a second through groove is formed in the middle of each boundary beam, the splicing assembly is spliced in the second through groove, a step is arranged at one end of each boundary beam, a first splicing hole is formed in the section of each step, a first through groove is formed in the middle of each step, the splicing assembly is spliced in the first through groove, a first splicing column is fixedly connected to the end portion, far away from the step, of each first splicing hole, and the first splicing column of one boundary beam is spliced in the first splicing hole of the other boundary beam.

Preferably, a second protrusion is fixedly connected to one side of the longitudinal beam, the second protrusion is matched with the first groove, T-shaped grooves are formed in the edges of the two ends of the longitudinal beam, the T-shaped grooves are detachably connected with the first connecting piece, the first connecting piece is of an I-shaped structure, a plurality of third through grooves are formed in the two side walls of the longitudinal beam, the cross beam is inserted into the third through grooves, fourth through grooves are formed in the third through grooves, the fourth through grooves are perpendicular to the third through grooves, sixth through grooves are formed in the side walls of the longitudinal beam, the sixth through grooves are parallel to the fourth through grooves, the inserting assembly is inserted into the fourth through grooves and the sixth through grooves, a clamping portion is arranged on the side walls of the longitudinal beam, and the clamping portion is detachably connected with the support arm.

Preferably, the clamping portion comprises a plurality of fifth through grooves formed in the side wall of the longitudinal beam, a pair of third connecting columns is inserted in the fifth through grooves of the two adjacent longitudinal beams on the outermost side, the third connecting columns are detachably connected with the support arm, the cross section of each third connecting column is square, an eighth through groove is formed in one end of each third connecting column, a second inserting hole is formed in the side wall of each eighth through groove, the eighth through grooves of the pair of third connecting columns are mutually attached, the axes of the second inserting holes of the pair of third connecting columns are coincident, a second connecting piece is inserted in each second inserting hole, a second inserting column is fixedly connected to the bottom of each second connecting piece, the second inserting column is inserted in each second inserting hole, and a locking portion is formed between each second connecting piece and the longitudinal beam.

Preferably, the locking part is provided with a first hole in the side wall of the longitudinal beam, the first hole is close to a semicircular hole in which one end of the fifth through groove is bent and arranged along the axis, the side wall of the second connecting piece is provided with a second hole, the top end of the second hole is communicated with a round hole, the second hole is attached to the first hole to form a cylindrical hole, and a steel ball is placed in the cylindrical hole.

Preferably, the two side edge portions of the cross beam are matched with the third through groove, a seventh through groove is formed in the side wall of the cross beam, which is in contact with the third through groove, the seventh through groove is perpendicular to the side wall of the cross beam, the plug-in component is plugged in the seventh through groove, second grooves are respectively formed in the other two side walls of the cross beam, the second grooves are matched with the support arms, and one end of the cross beam is plugged in the plug-in groove.

Preferably, the support arm is of an A-shaped structure, a reinforcing beam is fixedly connected to the middle of the support arm, a third protrusion is fixedly connected to the outer side of the bottom of the support arm and matched with the second groove, a ninth through groove is formed in the inner side of the bottom of the support arm, and the third connecting column is inserted into the ninth through groove.

Preferably, the plug-in assembly comprises a first connecting column and a second connecting column, the first connecting column is plugged in the first through groove and the sixth through groove, the second connecting column is plugged in the second through groove, the fourth through groove and the seventh through groove, and the cross sections of the first connecting column and the second connecting column are square.

The utility model has the following technical effects: the panel is used for bearing the pressure of water, and the boundary beam subassembly is used for consolidating the limit portion of panel, reinforcing overall structure's intensity, the longeron is used for consolidating the panel middle part, first connecting piece will the longeron is connected as an organic wholely, makes each longeron atress in coordination, and the crossbeam is located between the longeron, prevents to produce relative displacement between the longeron, the grafting subassembly is with the boundary beam subassembly, longeron and crossbeam link together, the support arm is used for supporting panel, wherein the panel, the boundary beam subassembly, the longeron, the crossbeam, the support arm, first connecting piece and grafting subassembly are the detachable connection mode, the drawback of traditional water conservancy project steel gate welding or screw connection has been avoided, each part is by the mould shaping, interchangeability is high, be convenient for the transportation, can be at on-site direct assembly, the equipment time has been saved, the quality problem of avoiding welding crack to cause has been reached and the effect integrality that improves the component.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in 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 invention, and it is obvious for those skilled in the art to obtain other drawings without inventive exercise.

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

FIG. 2 is a schematic view of a panel structure according to the present invention;

FIG. 3 is a schematic view of the construction of the boundary beam of the present invention;

FIG. 4 is a schematic structural view of a stringer in accordance with the present invention;

FIG. 5 is a right side view of the stringer of the present invention;

FIG. 6 is an enlarged view of a portion A of FIG. 4;

FIG. 7 is a schematic view of a cross beam structure according to the present invention;

FIG. 8 is a schematic view of a support arm structure according to the present invention;

FIG. 9 is a schematic view of a first connector structure according to the present invention;

FIG. 10 is a schematic view of a second connector according to the present invention;

FIG. 11 is a schematic view of a third connecting column according to the present invention;

FIG. 12 is a schematic view of the assembly of the panel and sill assembly of the present invention;

FIG. 13 is a schematic view of the assembly of the face plate, the sill assembly and the stringer of the present invention;

FIG. 14 is a schematic view of the assembly of the face plate, the side rail assembly, the longitudinal rail, the transverse rail, the first connector and the plug assembly of the present invention;

FIG. 15 is a schematic view of the assembly of the face plate, the side rail assembly, the longitudinal rail, the transverse rail, the first connecting member, the plug assembly and the arm of the present invention;

FIG. 16 is a schematic view of the assembly of the stringers, arms, third connecting stud and second connecting member of the present invention;

wherein, 1, a panel; 2. a boundary beam; 3. a stringer; 4. a cross beam; 5. a support arm; 6. a first connecting member; 7. a second connecting member; 8. a first connecting column; 9. a second connecting column; 10. a third connecting column; 101. a first groove; 102. inserting grooves; 201. a first protrusion; 202. a second through groove; 203. a first through groove; 204. a first plug-in column; 205. a first plug hole; 301. A second protrusion; 302. a T-shaped groove; 303. a third through groove; 304. a fourth through groove; 305. a first duct; 306. a fifth through groove; 307. a sixth through groove; 401. a seventh through groove; 402. a second groove; 501. reinforcing the beam; 502. a ninth through groove; 503. a third protrusion; 701. a second plug column; 703. a second duct; 702. a circular hole; 1001. an eighth through groove; 1002. and a second plug hole.

Detailed Description

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

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in further detail below.

Referring to fig. 1-16, the utility model provides a novel assembly type hydraulic steel gate, which comprises a panel 1, wherein side beam assemblies are symmetrically and detachably connected to the inner side edge of the panel 1, a plurality of longitudinal beams 3 are arranged between the two side beam assemblies, the side edges of the longitudinal beams 3 are detachably connected with the inner side of the panel 1, the end parts of the adjacent longitudinal beams 3 are detachably connected with a first connecting piece 6, the side walls of the adjacent longitudinal beams 3 are detachably connected with a plurality of cross beams 4, the end parts of the cross beams 4 are spliced with the inner side of the panel 1, the side wall of each side beam assembly, the side walls of the longitudinal beams 3 and the side walls of the cross beams 4 are jointly spliced with a splicing assembly, a support arm 5 is detachably connected between the two longitudinal beams 3 positioned on the outermost side, and the side wall of the support arm 5 is connected with the side wall of the cross beam 4 in a matched mode.

The panel 1 is used for bearing the pressure of a water body, the boundary beam component is used for reinforcing the edge of the panel 1 and enhancing the strength of the whole structure, the longitudinal beams 3 are used for reinforcing the middle of the panel 1, the longitudinal beams 3 are connected into a whole by the first connecting piece 6, so that the longitudinal beams 3 are stressed in a coordinated manner, the cross beams 4 are positioned between the longitudinal beams 3 and prevent the longitudinal beams 3 from generating relative displacement, the boundary beam component, the longitudinal beams 3 and the cross beams 4 are connected together by the plug-in component, the support arm 5 is used for supporting the panel 1, wherein the panel 1, the edge beam component, the longitudinal beam 3, the cross beam 4, the support arm 5, the first connecting piece 6 and the inserting component are all in a detachable connection mode, the defect of welding or screw connection of the traditional hydraulic steel gate is avoided, each part is formed by a die, the interchangeability is high, the transportation is convenient, the welding method can be directly assembled on site, so that the assembling time is saved, and the effects of avoiding quality problems caused by welding cracks and improving the integrity of the component are achieved.

According to the further optimized scheme, a plurality of first grooves 101 are formed in the inner side wall of the panel 1, the cross sections of the first grooves 101 are of isosceles trapezoid structures, and the edge beam assembly and the longitudinal beam 3 are detachably connected with the panel 1 through the first grooves 101; a plurality of inserting grooves 102 are formed in the middle of the inner side wall of the panel 1, the inserting grooves 102 are located between the adjacent first grooves 101, and the cross beam 4 is inserted into the panel 1 through the inserting grooves 102.

The panel 1 is the main atress part that bears, and first recess 101 opening part length is less than bottom surface length, and boundary beam subassembly and longeron 3 insert from the tip of first recess 101, and inserting groove 102 is used for fixed crossbeam 4 to carry on spacingly to crossbeam 4.

Further optimize the scheme, the boundary beam subassembly includes boundary beam 2 that the symmetry set up, 2 outside limit portion rigid couplings of boundary beam have first arch 201, first arch 201 and first recess 101 looks adaptation, second logical groove 202 has been seted up at 2 middle parts of boundary beam, the grafting subassembly is pegged graft in second logical groove 202, 2 one end of boundary beam is equipped with the step, first spliced eye 205 has been seted up to the section department of step, first logical groove 203 has been seted up at the step middle part, the grafting subassembly is pegged graft in first logical groove 203, first spliced eye 205 tip rigid coupling is kept away from to the step has first spliced pole 204, the first spliced pole 204 of one of them boundary beam 2 is pegged graft in first spliced eye 205 of another boundary beam 2.

The first protrusion 201 is matched with the first groove 101, when the two boundary beams 2 are assembled, the two boundary beams 2 can be simultaneously inserted from two ends of the first groove 101 respectively until the first plug-in column 204 is inserted into the bottom of the first plug-in hole 205, so that the assembling time is reduced, and the two boundary beams 2 are kept in the middle of the first groove 101.

Further optimization scheme, 3 one sides rigid couplings of longeron have the second arch 301, the protruding 301 and the first recess 101 looks adaptation of second, 3 both ends limit portions of longeron have seted up T type groove 302, T type groove 302 can be dismantled with first connecting piece 6 and be connected, first connecting piece 6 is the I shape structure, 3 both sides walls of longeron have seted up a plurality of third and have led to groove 303, crossbeam 4 pegs graft in third through groove 303, the inside fourth through groove 304 that has seted up of third through groove 303, fourth through groove 304 is perpendicular with third through groove 303, the sixth through groove 307 has been seted up to 3 lateral walls of longeron, sixth through groove 307 is parallel with fourth through groove 304, the grafting subassembly pegs graft in fourth through groove 304 and sixth through groove 307, 3 lateral walls of longeron are provided with joint portion, joint portion can dismantle with support arm 5 and be connected.

The second protrusion 301 is matched with the first groove 101, the T-shaped groove 302 is used for installing the first connecting piece 6, the adjacent longitudinal beams 3 are connected together through the first connecting piece 6, the longitudinal beams 3 can be stressed cooperatively, the overall strength of the longitudinal beams 3 is enhanced, the two adjacent third through grooves 303 are in contact with the cross beam 4, and the sixth through groove 307 and the fourth through groove 304 are used for connecting the plugging assembly.

Further optimize the scheme, joint portion is including seting up in a plurality of fifth logical grooves 306 of longeron 3 lateral wall, it has a pair of third spliced pole 10 to peg graft in the fifth logical groove 306 of two adjacent longerons 3 in the outside, third spliced pole 10 can dismantle with support arm 5 and be connected, third spliced pole 10 cross-section is square, eighth logical groove 1001 has been seted up to third spliced pole 10 one end, second spliced eye 1002 has been seted up to the lateral wall of eighth logical groove 1001, the laminating of eighth logical groove 1001 of a pair of third spliced pole 10 each other, the coincidence of second spliced eye 1002 axis of a pair of third spliced pole 10, it has second connecting piece 7 to peg graft in second spliced eye 1002, 7 bottom rigid couplings of second connecting piece have second spliced pole 701, second spliced pole 701 pegs graft in second spliced eye 1002, be equipped with the sticking department between second connecting piece 7 and the longeron 3.

Insert the space between two longerons 3 with support arm 5 bottom along inserting crossbeam 4, insert the fifth through-groove 306 with third spliced pole 10 from the longeron 3 outside, until the eighth through-groove 1001 of two third spliced poles 10 laminates each other, third spliced pole 10 middle part and support arm 5 joint, insert the second spliced pole 701 of second connecting piece 7 in second spliced eye 1002 again, prevent that two third spliced poles 10 from breaking away, the back that the installation of third spliced pole 10 was finished, support arm 5 and longeron 3 are even as an organic whole.

In a further optimized scheme, the locking part comprises a first duct 305 arranged on the side wall of the longitudinal beam 3, one end, close to the fifth through groove 306, of the first duct 305 is a semicircular duct with a bent axis, a second duct 703 is arranged on the side wall of the second connecting piece 7, the top end of the second duct 703 is communicated with a circular hole 702, the second duct 703 is attached to the first duct 305 to form a cylindrical duct, and a steel ball is placed in the cylindrical duct.

The steel ball is placed in the circular hole 702, the steel ball and the first hole channel 305 form a cylindrical hole channel along the second hole channel 703 and roll until the steel ball rolls to the bottom of the hole channel, and the steel ball prevents the second connecting piece 7 from moving upwards due to the bending arrangement of the bottom of the hole channel, so that the second connecting piece 7 is locked.

Further optimization scheme, 4 both sides limit portion of crossbeam and third through groove 303 looks adaptation, and the seventh through groove 401 has been seted up to the lateral wall that crossbeam 4 and third through groove 303 contact, and seventh through groove 401 is perpendicular with 4 lateral walls of crossbeam, and the grafting subassembly is pegged graft in seventh through groove 401, and second recess 402 has been seted up respectively to two other lateral walls of crossbeam 4, and second recess 402 and support arm 5 looks adaptation, and crossbeam 4 one end is pegged graft in inserting groove 102.

The cross beam 4 is arranged between two adjacent third through grooves 303, the bottom of the cross beam 4 is inserted into the insertion groove 102, the seventh through groove 401 is used for being connected with the insertion assembly, the section of the second groove 402 is the same as that of the first groove 101, and the second groove 402 is used for being matched with the support arm 5.

Further optimization scheme, support arm 5 is A style of calligraphy structure, and 5 middle part rigid couplings of support arm have reinforcing beam 501, and 5 bottom outside rigid couplings of support arm have third arch 503, and third arch 503 and second recess 402 looks adaptation, and the ninth logical groove 502 has been seted up to 5 bottom inboard of support arm, and third spliced pole 10 pegs graft in the ninth logical groove 502.

The reinforcing beam 501 is used for reinforcing the support arm 5, the third protrusion 503 is inserted from the top of the second groove 402 and used for guiding when the support arm 5 is installed, and the ninth through groove 502 is clamped with the middle part of the third connecting column 10 to limit the displacement of the support arm 5.

According to a further optimized scheme, the plug-in assembly comprises a first connecting column 8 and a second connecting column 9, the first connecting column 8 is plugged in the first through groove 203 and the sixth through groove 307, the second connecting column 9 is plugged in the second through groove 202, the fourth through groove 304 and the seventh through groove 401, and the cross sections of the first connecting column 8 and the second connecting column 9 are square. The first connecting column 8 and the second connecting column 9 connect the boundary beam 2, the longitudinal beam 3 and the cross beam 4 together, so that the positions of all parts are mutually limited.

A design method of a novel assembly type hydraulic steel gate is used for designing the novel assembly type hydraulic steel gate and comprises the following steps:

(1) comprehensively knowing the overall planning of the hydraulic structure, specifically comprising the function, scale and operation characteristics of the hydraulic structure;

(2) determining the orifice size, the orifice number and the acting water head of the hydraulic steel gate according to the specific requirements of the hydraulic building;

(3) determining a gate-shaped plane steel gate and an arc-shaped steel gate of the hydraulic steel gate according to the characteristics and application conditions of different hydraulic steel gates;

(4) according to the arrangement requirement of the hydraulic steel gate, calculating and designing the structure and parts of the hydraulic steel gate according to the design specification of the existing hydraulic steel gate, and stably calculating and designing the thickness of a panel 1, the number of longitudinal beams 3, the height of a cross beam 4, the number of cross beams 4, the thickness of a lifting lug plate and a support arm 5 of the hydraulic steel gate;

(5) according to the calculated and designed gate structure and the connection forms of different structures, detachable connection structures are arranged on the structures which are connected with each other;

(6) and finally, conveying the parts of the whole hydraulic steel gate structure to a construction site, assembling and splicing on the construction site, performing anticorrosive spraying after the whole structure is assembled and spliced completely, and completing the assembling and splicing of the hydraulic steel gate structure after the anticorrosive spraying is fully dried.

The assembly process of the utility model is as follows:

installing the boundary beams 2, installing the boundary beams 2 from two ends of a first groove 101 at the same time, aligning the first protrusion 201 with the first groove 101, pushing the first protrusion 201 into the first groove 101 until a first plug-in column 204 is inserted into the bottom of a first plug-in hole 205, adjusting the two boundary beams 2 to be positioned in the middle of the first groove 101, installing the boundary beams 2 on the other side by adopting the same method, installing the boundary beams 2 on two sides in opposite directions at the same time, accelerating the installation progress, positioning the boundary beams 2 at two ends of a panel 1, playing a role in reinforcing the edge of the panel 1, preventing the edge of the panel 1 from torsional deformation, and simultaneously connecting the boundary beams 2 with the longitudinal beams 3, the cross beams 4 and other parts into a whole through plug seat components, thereby improving the performance of resisting deformation of the whole structure;

installing the longitudinal beams 3, aligning the second bulge 301 to one end of the first groove 101, pushing the second bulge 301 into the first groove 101 until the edge of the second bulge 301 is flush with the edge of the first groove 101, wherein the second bulge 301 is not in transition fit with the first groove 101, sequentially installing all the longitudinal beams 3 by adopting the installation method, after all the longitudinal beams 3 are installed, installing the first connecting piece 6 in the T-shaped groove 302, attaching the longitudinal beams 3 to the bending surface of the panel 1 to prevent the panel 1 from bending deformation under impact force, connecting the longitudinal beams 3 with the edge beams 2 under the action of the plug-in assembly, enhancing the integral deformation resistance of the device, and connecting the longitudinal beams 3 into a whole by the first connecting piece 6;

mounting the cross beam 4, aligning the end part of the cross beam 4 with the two adjacent third through grooves 303, and inserting downwards until the bottom end of the cross beam 4 is contacted with the bottom of the inserting groove 102; the installation plug assembly inserts first spliced pole 8 in proper order and leads to groove 203 and the sixth through groove 307, inserts second spliced pole 9 in proper order and leads to groove 202, fourth through groove 304 and the seventh through groove 401 in the second, and crossbeam 4 prevents that adjacent longeron 3 from producing the displacement to both sides, and crossbeam 4 links as an organic whole through plug assembly and integrated device simultaneously.

Mounting the support arm 5, sliding the third protrusion 503 at the bottom of the support arm 5 downwards along the second groove 402, the second groove 402 prevents the support arm 5 from shaking towards two sides, inserting the third connecting column 10 through the fifth through groove 306 of the outer side longitudinal beam 3 at the two ends until the eighth through grooves 1001 of the two third connecting columns 10 are mutually attached, then inserting the second connecting piece 7 into the second inserting hole 1002 of the third connecting column 10, finally putting the steel ball into the round hole 702, attaching the steel ball along the second hole 703 and the first hole 305 to form a cylindrical hole to roll downwards, until the steel ball rolls to the bottom end of the hole, clamping the second connecting piece 7 once the steel ball rolls to the bottom end of the hole, and preventing the second connecting piece 7 from falling off in the using process.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, are merely for convenience of description of the present invention, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention, and do not limit the scope of the present invention, and various modifications and improvements of the technical solutions of the present invention can be made by those skilled in the art without departing from the spirit of the present invention, and the technical solutions of the present invention are within the scope of the present invention defined by the claims.

Claims (9)

1. The utility model provides a novel assembled water conservancy project steel gate which characterized in that: including panel (1), panel (1) inboard limit portion symmetry can be dismantled and be connected with the boundary beam subassembly, two be provided with a plurality of longerons (3) between the boundary beam subassembly, longeron (3) limit portion with panel (1) inboard can be dismantled and connect, and is adjacent longeron (3) tip can be dismantled and be connected with first connecting piece (6), and is adjacent longeron (3) lateral wall can be dismantled and be connected with a plurality of crossbeams (4), crossbeam (4) tip with panel (1) inboard is pegged graft, the boundary beam subassembly longeron (3) with crossbeam (4) lateral wall is pegged graft jointly and is had grafting subassembly, is located the outside two can dismantle between longeron (3) and be connected with support arm (5), support arm (5) lateral wall with crossbeam (4) lateral wall cooperation is connected.

2. The novel assembled hydraulic steel gate of claim 1, wherein: a plurality of first grooves (101) are formed in the inner side wall of the panel (1), the cross sections of the first grooves (101) are of isosceles trapezoid structures, and the edge beam assembly and the longitudinal beam (3) are detachably connected with the panel (1) through the first grooves (101); a plurality of inserting grooves (102) are formed in the middle of the inner side wall of the panel (1), the inserting grooves (102) are located between the adjacent first grooves (101), and the cross beam (4) is inserted into the panel (1) through the inserting grooves (102).

3. The novel assembled hydraulic steel gate of claim 2, wherein: the boundary beam component comprises boundary beams (2) which are symmetrically arranged, a first protrusion (201) is fixedly connected to the outer side edge portion of each boundary beam (2), the first protrusion (201) is matched with the first groove (101), a second through groove (202) is formed in the middle of each boundary beam (2), the inserting component is inserted into the second through groove (202), a step is arranged at one end of each boundary beam (2), a first inserting hole (205) is formed in the section of the step, a first through groove (203) is formed in the middle of the step, the inserting component is inserted into the first through groove (203), a first inserting column (204) is fixedly connected to the end portion of the first inserting hole (205) and far away from the step, and the first inserting column (204) of each boundary beam (2) is inserted into the first inserting hole (205) of the other boundary beam (2).

4. The novel assembled hydraulic steel gate of claim 3, wherein: a second bulge (301) is fixedly connected to one side of the longitudinal beam (3), the second bulge (301) is matched with the first groove (101), T-shaped grooves (302) are formed in the edge portions of two ends of the longitudinal beam (3), the T-shaped grooves (302) are detachably connected with the first connecting piece (6), the first connecting piece (6) is of an I-shaped structure, a plurality of third through grooves (303) are formed in two side walls of the longitudinal beam (3), the cross beam (4) is inserted into the third through grooves (303), a fourth through groove (304) is formed in the third through groove (303), the fourth through groove (304) is perpendicular to the third through groove (303), a sixth through groove (307) is formed in the side wall of the longitudinal beam (3), the sixth through groove (307) is parallel to the fourth through groove (304), and the inserting assembly is inserted into the fourth through groove (304) and the sixth through groove (307), longeron (3) lateral wall is provided with joint portion, joint portion with support arm (5) can be dismantled and be connected.

5. The novel assembled hydraulic steel gate of claim 4, wherein: the clamping part comprises a plurality of fifth through grooves (306) formed in the side walls of the longitudinal beams (3), a pair of third connecting columns (10) are inserted in the fifth through grooves (306) of two adjacent longitudinal beams (3) on the outermost sides, the third connecting columns (10) are detachably connected with the support arm (5), the cross sections of the third connecting columns (10) are square, eighth through grooves (1001) are formed in one ends of the third connecting columns (10), second inserting holes (1002) are formed in the side walls of the eighth through grooves (1001), the eighth through grooves (1001) of the pair of third connecting columns (10) are mutually attached, the axes of the second inserting holes (1002) of the pair of third connecting columns (10) are overlapped, second connecting pieces (7) are inserted in the second inserting holes (1002), and second inserting columns (701) are fixedly connected to the bottoms of the second connecting pieces (7), the second inserting column (701) is inserted into the second inserting hole (1002), and a locking part is arranged between the second connecting piece (7) and the longitudinal beam (3).

6. The novel assembled hydraulic steel gate of claim 5, wherein: the locking part is including seting up in first pore (305) of longeron (3) lateral wall, first pore (305) are close to the semicircle type pore that fifth logical groove (306) one end set up for the axis is crooked, second pore (703) have been seted up to second connecting piece (7) lateral wall, second pore (703) top intercommunication has round hole (702), second pore (703) with first pore (305) laminating constitutes cylinder type pore, place the steel ball in the cylinder type pore.

7. The novel assembled hydraulic steel gate of claim 5, wherein: the side parts of two sides of the cross beam (4) are matched with the third through groove (303), a seventh through groove (401) is formed in the side wall, contacted with the third through groove (303), of the cross beam (4), the seventh through groove (401) is perpendicular to the side wall of the cross beam (4), the plug-in component is plugged in the seventh through groove (401), second grooves (402) are formed in the other two side walls of the cross beam (4) respectively, the second grooves (402) are matched with the support arms (5), and one end of the cross beam (4) is plugged in the plug-in groove (102).

8. The novel assembled hydraulic steel gate of claim 7, wherein: the support arm (5) is of an A-shaped structure, a reinforcing beam (501) is fixedly connected to the middle of the support arm (5), a third protrusion (503) is fixedly connected to the outer side of the bottom of the support arm (5), the third protrusion (503) is matched with the second groove (402), a ninth through groove (502) is formed in the inner side of the bottom of the support arm (5), and the third connecting column (10) is inserted into the ninth through groove (502).

9. The novel assembled hydraulic steel gate of claim 7, wherein: the plug-in assembly comprises a first connecting column (8) and a second connecting column (9), the first connecting column (8) is plugged in the first through groove (203) and the sixth through groove (307), the second connecting column (9) is plugged in the second through groove (202), the fourth through groove (304) and the seventh through groove (401), and the cross sections of the first connecting column (8) and the second connecting column (9) are square.

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