CN113515801A - Method for calculating bearing capacity of K-shaped steel pipe penetration welding joint with stiffening rib - Google Patents

Abstract

The invention discloses a calculation method for the bearing capacity of a steel pipe K-shaped penetration welding joint with stiffening, and relates to the field of structural calculation of electric power technology and constructional engineering. It comprises the following steps: step 1: calculating to obtain an intermediate parameter psi_n(ii) a Step 2: calculating the pipe diameter ratio beta and the intermediate parameter psi of the pressure branch pipe and the main pipe_β(ii) a And step 3: calculating to obtain an intermediate parameter psi_a(ii) a And 4, step 4: calculating to obtain the partial contribution term N of the non-stiffened node_cK(ii) a And 5: calculating to obtain the effective length l of the node plate on the pressure side_ec(ii) a Step 6: calculating to obtain contribution term N of the gusset part_cP(ii) a And 7: calculating to obtain a ring plate part contribution item N_cR(ii) a Step 8, calculating to obtain the bearing capacity N of the penetration welding node with the stiffening rib_cKPRThe tension branch pipe has a bearing capacity N of a stiffening intersecting welding joint_tKPR. The steel pipe K-shaped penetration welding joint obtained by the calculation method has high safety performance and low construction cost; the invention can be widely applied to the design of the transmission line in the K-shaped steel pipe with the stiffening intersecting welding joint.

Description

Method for calculating bearing capacity of K-shaped steel pipe penetration welding joint with stiffening rib

Technical Field

The invention relates to the field of structural calculation of electric power technology and constructional engineering, in particular to a method for calculating the bearing capacity of a K-shaped stiffening intersecting welding joint of a steel pipe.

Background

The steel pipe member has excellent structural performance and attractive appearance, and the steel pipe truss structure formed by direct welding is widely applied to the structural fields of electric power, buildings, oceans, machinery and the like; the K-shaped intersecting joint is an important connection form of a steel pipe tower structure of the power transmission line, and the actual engineering often needs to locally reinforce the joint part so as to improve the bearing capacity and rigidity of the joint; however, in the design standards at home and abroad, the calculation method of the bearing capacity of the K-shaped stiffening intersecting node is still incomplete.

At present, the design standards of steel structures (GB50017-2017), the design specifications of American steel structure buildings (ANSI/AISC 360-10), and the European code 3: steel structure design-parts 1-8: the node design (EN 1993-1-8) and the like make detailed regulations on a bearing capacity calculation method of a K-shaped stiffening-free steel pipe intersecting welding node and provide a practical calculation formula; although the methods are different in formula expression, the methods are relatively mature, and are verified by related tests and simulation analysis, and are widely adopted in engineering design at present; however, the bearing capacity calculation method of the stiffening intersecting welding node has no systematic design method at present.

Through tests, the bearing capacity of the intersecting welding joint is obviously improved after the stiffening plate is arranged, and if the bearing capacity of the intersecting welding joint is reasonably considered in design, the steel pipe joint is more economical and reasonable in design, so that a brand-new calculation method for the bearing capacity of the steel pipe K-shaped intersecting welding joint with stiffening considering the stiffening contribution effect is urgently needed to be researched, the calculation result is more consistent with the test condition, and the economy of the design of the steel pipe K-shaped intersecting welding joint with stiffening is further improved.

At present, documents for researching a design method of the bearing capacity of a K-type stiffening node are few, and a design method of the bearing capacity of the K-type stiffening node only with a gusset plate is given in a text of a test research and a design calculation method of the bearing capacity of the K-type stiffening node through stiffening welding (Wang Xiao Jian and the like), and the action of a ring plate cannot be considered; when the K-type node is loaded, the rotation of the node plate can cause compression on the branch pipe, and local buckling occurs, and when the radius-thickness ratio is large, the phenomenon is obvious; the branch pipes adopted in the article of Wangxiao construction and the like are all in the condition of small diameter-thickness ratio, and the diameter-thickness ratio of the pipe fittings commonly used for the non-transmission line is not suitable for the condition of large diameter-thickness ratio of the branch pipes.

Therefore, it is necessary to develop a calculation method for the bearing capacity of the K-shaped stiffened intersecting welding joint of the steel pipe, which considers the contribution of the ring plate to the bearing capacity of the joint, and can accurately calculate the bearing capacity of the joint under the condition of large branch pipe diameter and thickness based on extensive tests and numerical simulation.

Disclosure of Invention

The invention aims to overcome the defects of the background technology and provides a method for calculating the bearing capacity of a K-shaped stiffening intersecting welding joint of a steel pipe.

In order to achieve the purpose, the technical scheme of the invention is as follows: a method for calculating the bearing capacity of a steel pipe K-shaped penetration welding joint with stiffening comprises the following steps:

step 1: determining the smaller value sigma of the pressure stress of the main pipe on two sides of the node and the yield strength f of the steel of the main pipe_yCalculating to obtain an intermediate parameter psi_n；

Intermediate parameter psi_nCalculated by formula (1):

wherein, sigma is the smaller value of the pressure stress of the main pipes at two sides of the node, and when the main pipes at two sides or one side of the node are pulled, 0 is taken;

step 2: determining the diameter d of a pressure branch_cAnd the diameter D of the main pipe, calculating the pipe diameter ratio beta of the pressure branch pipe to the main pipe and the intermediate parameter psi_β；

The pipe diameter ratio beta is obtained by calculating the formula (2), and the intermediate parameter psi_βThe following calculation results in:

β＝d_cformula/D (2)

And step 3: based on the thickness T of the main pipe, the gap a between the two branch pipes, the diameter D of the main pipe and the pipe diameter ratio beta, an intermediate parameter psi is obtained through calculation_a；

The intermediate parameter ψ a is calculated by formula (4):

and 4, step 4: based on the included angle theta between the pressure branch pipe and the main pipe_cMain pipe thickness T, intermediate parameter psi_n、ψ_β、ψ_aDesign value f of the main pipe steel strength_mCalculating the contribution term N of the K-shaped stiffening intersecting welding joint bearing capacity without stiffening node part of the pressurized branch pipe_cK；

N_cKCalculated by equation (5):

and 5: nominal length B of stiffening plate based on pressed branch pipe side_cMain pipe diameter D, pressure branch pipe diameter D_cThe included angle theta between the pressure branch pipe and the main pipe_cAnd calculating to obtain the effective length l of the gusset plate on the pressure receiving side_ec；

Effective length l of pressure side gusset plate_ecCalculated by equation (6):

step 6: based on the diameter D of the main pipe, the effective length l of the pressure side gusset plate_ecDesign value f of steel strength of gusset plate_pThickness T of main pipe, angle theta between pressure branch pipe and main pipe_cThe intermediate parameter psi_nCalculating the contribution term N of the K-shaped gusset plate part with the bearing capacity of the stiffening intersecting welding node_cP；

N_cPCalculated by equations (7) to (9):

wherein A is_cIs the total cross-sectional area of the pressure branch pipe, f_cFor the design value of the strength of the pressed branch pipe,

and

are all intermediate coefficients;

and 7: based on the diameter D of the main pipe, the thickness T of the main pipe and the thickness T of the ring plate_rHeight h of ring plate_rCalculating the contribution term N of the K-shaped annular plate part with the bearing capacity of the stiffening intersecting welding joint_cR；

N_cRCalculated by equation (10):

in the formula, alpha is radian; when the ring plate is a full ring, taking alpha as 1.1 pi; when the ring plates are 1/4 rings and semi-rings, alpha is the radian of the ring plates; when in use

When it is taken

Step 8, based on the K-shaped non-stiffened node part contribution item N with stiffened intersecting welding node bearing capacity_cKK-shaped node plate part contribution item N with stiffening intersecting welding node bearing capacity_cPK-shaped ring plate part contribution item N with stiffening intersecting welding node bearing capacity_cRCalculating the bearing capacity N of the stiffening intersecting welding joint of the K-shaped pressure branch pipe_cKPRThe tension branch pipe has a bearing capacity N of a stiffening intersecting welding joint_tKPR；

Bearing capacity N of penetration welding joint with stiffening rib for K-shaped compressed branch pipe_cKPRThe bearing capacity N of the intersecting welding joint with the stiffening of the tension branch pipe is calculated according to the formula (11)_tKPRCalculated according to equation (12):

compared with the prior art, the invention has the following advantages:

1) the invention provides a calculation method for the bearing capacity of a K-shaped stiffening intersecting welding joint of a steel pipe, which considers the contribution of a stiffening plate and a ring plate for the first time, and comprehensively considers the size and the strength of a main pipe, a branch pipe, the stiffening plate and the ring plate and the influence of the ring plate arrangement to obtain the bearing capacity of the joint of a stressed branch pipe and a tensioned branch pipe; because the bearing capacity calculation of the steel pipe K-shaped stiffened intersecting welding joint needs a plurality of parameters to be considered, the bearing capacity calculation method is obtained by adopting finite element numerical simulation to carry out parametric analysis on the basis of test and theoretical analysis and fitting based on the data.

2) The steel pipe K-shaped penetration welding joint obtained by the calculation method has high safety performance and low construction cost; the invention can be widely applied to the design of the transmission line in the K-shaped steel pipe with the stiffening intersecting welding joint.

3) Compared with the existing standard and the text of 'reinforced intersecting welding K-type node bearing capacity test research and design calculation method', such as Wang Xiao Jian, the calculation method can consider the contribution of the ring plate to the node bearing capacity, and meanwhile, based on extensive tests and numerical simulation, for the larger diameter of the branch pipe, the calculation method can also accurately calculate the bearing capacity.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of the ring plate being a full ring plate.

Fig. 3 is a schematic structural view of the ring plate being a semi-ring plate.

Fig. 4 is a schematic structure diagram of 1/4 ring plates.

Detailed Description

The embodiments of the present invention will be described in detail with reference to the accompanying drawings, which are not intended to limit the present invention, but are merely exemplary. While the advantages of the invention will be apparent and readily appreciated by the description.

As shown in FIG. 1, D is the main tube diameter, T is the main tube thickness, D_cTo the diameter of the pressure branch, t_cThickness of the pressed branch pipe, d_tIs the tension leg diameter, t_tIs the tension leg thickness, θ_cIs the angle between the pressure branch pipe and the main pipe, theta_tIs the angle between the pressure branch pipe and the main pipe, a is the gap between the two branch pipes, h_rIs the ring plate height, t_rIs the thickness of the ring plate, B_cNominal length of stiffening plate at the side of the pressed branch pipe, B_tIs the nominal length of the stiffening plate at the side of the tension branch pipe_ecFor the effective length of the gusset plate on the compression side, /)_etThese are the basic dimensional parameters required for the nodal load capacity calculation for the effective length of the tension side nodal plate.

A method for calculating the bearing capacity of a steel pipe K-shaped penetration welding joint with stiffening comprises the following steps:

step 1: determining the smaller value sigma of the pressure stress of the main pipe on two sides of the node and the yield strength f of the steel of the main pipe_yCalculating to obtain an intermediate parameter psi_n；

Intermediate parameter psi_nCalculated by formula (1):

wherein, sigma is the smaller value of the pressure stress of the main pipes at two sides of the node, and when the main pipes at two sides or one side of the node are pulled, 0 is taken;

step 2: determining the diameter d of a pressure branch_cAnd the diameter D of the main pipe, calculating the pipe diameter ratio beta of the pressure branch pipe to the main pipe and the intermediate parameter psi_β；

The pipe diameter ratio beta is obtained by calculating the formula (2), and the intermediate parameter psi_βThe following calculation results in:

β＝d_cformula/D(2)

And step 3: based on the thickness T of the main pipe, the gap a between the two branch pipes, the diameter D of the main pipe and the pipe diameter ratio beta, an intermediate parameter psi is obtained through calculation_a；

The intermediate parameter ψ a is calculated by formula (4):

and 4, step 4: based on the included angle theta between the pressure branch pipe and the main pipe_cMain pipe thickness T, intermediate parameter psi_n、ψ_β、ψ_aDesign value f of the main pipe steel strength_mCalculating the contribution term N of the K-shaped stiffening intersecting welding joint bearing capacity without stiffening node part of the pressurized branch pipe_cK；

N_cKCalculated by equation (5):

and 5: nominal length B of stiffening plate based on pressed branch pipe side_cMain pipe diameter D, pressure branch pipe diameter D_cThe included angle theta between the pressure branch pipe and the main pipe_cAnd calculating to obtain the effective length l of the gusset plate on the pressure receiving side_ec；

Effective length l of pressure side gusset plate_ecCalculated by equation (6):

step 6: based on the diameter D of the main pipe, the effective length l of the pressure side gusset plate_ecDesign value f of steel strength of gusset plate_pThickness T of main pipe, angle theta between pressure branch pipe and main pipe_cThe intermediate parameter psi_nCalculatingObtaining the contribution term N of the node plate part of the K-shaped node with the stiffening penetration welding node bearing capacity_cP；

N_cPCalculated by equations (7) to (9):

wherein A is_cIs the total cross-sectional area of the pressure branch pipe, f_cFor the design value of the strength of the pressed branch pipe,

and

are all intermediate coefficients;

and 7: based on the diameter D of the main pipe, the thickness T of the main pipe and the thickness T of the ring plate_rHeight h of ring plate_rCalculating the contribution term N of the K-shaped annular plate part with the bearing capacity of the stiffening intersecting welding joint_cR；

N_cRCalculated by equation (10):

in the formula, alpha is radian; when the ring plate is a full ring plate, taking alpha as 1.1 pi; when the ring plate is a semi-ring plate, an 1/4 ring plate or a ring plate is arranged, alpha is the radian of the ring plate; when in use

When it is taken

Step 8, based on the K-shaped non-stiffened node part contribution item N with stiffened intersecting welding node bearing capacity_cKK-shaped node plate part contribution item N with stiffening intersecting welding node bearing capacity_cPK-shaped ring plate part contribution item N with stiffening intersecting welding node bearing capacity_cRCalculating the bearing capacity N of the stiffening intersecting welding joint of the K-shaped pressure branch pipe_cKPRThe tension branch pipe has a bearing capacity N of a stiffening intersecting welding joint_tKPR；

Bearing capacity N of penetration welding joint with stiffening rib for K-shaped compressed branch pipe_cKPRThe bearing capacity N of the intersecting welding joint with the stiffening of the tension branch pipe is calculated according to the formula (11)_tKPRCalculated according to equation (12):

examples

Taking a typical K-shaped penetration welding node with stiffening ribs as an example, the basic size parameters are as follows:

the diameter D of the main pipe is 406mm, the thickness T of the main pipe is 8mm, and the diameter D of the pressure branch pipe_c194mm, compressed leg thickness t_c8mm, diameter d of tension leg_t194mm, tensile leg thickness t_tIs 8mm, and the included angle theta between the pressure branch pipe and the main pipe_cIs 50 degrees, and the included angle theta between the tension branch pipe and the main pipe_tIs 40 degrees, the clearance a between the two branch pipes is 134.7mm, and the height h of the gusset plate_pIs 300mm, and the gusset plate thickness t_pIs 8mm, and adopts a full ring plate with a ring plate height h_rIs 40mm, and the thickness t of the ring plate_rIs 8mm, and the nominal length B of the stiffening plate at the side of the pressed branch pipe_c470mm, the nominal length B of the stiffening plate at the side of the tension branch pipe_tIs 542mm, and the effective length l of the gusset plate at the pressure side_ec173.0mm, the effective length l of the tension side gusset plate_etIs 149 mm.

The joint bearing capacity of the K-shaped stressed branch pipe and the K-shaped stressed branch pipe with the stiffening intersecting welding and the tension branch pipe is calculated according to the calculation method of the invention, and the joint bearing capacity is set according to the steel structureSection 13.3.2 of standard (GB50017-2017) does not consider node bearing capacity of contribution effect of node plates and ring plates, and for convenience of calculation, yield strength is adopted during calculation, the material of a main pipe is Q420, and the yield strength is 420N/mm²Design strength 375N/mm²The materials of other parts are Q355, and the yield strength is 355N/mm²Designed strength of 305N/mm²(ii) a The smaller value sigma of the compressive stress of the main pipes on the two sides of the node is 0; the results are shown in table 1, which indicates that the contribution of the node plate and the ring plate is considered to be very significant, the bearing capacity of the node is obviously improved, and the calculation of the bearing capacity of the node of the K-shaped stiffened coherent welded pressed branch pipe and the tensioned branch pipe is more economic and reasonable when the calculation method of the bearing capacity of the K-shaped stiffened coherent welded node of the steel pipe is used for calculating the bearing capacity of the node of the K-shaped stiffened coherent welded pressed branch pipe and the tensioned branch pipe.

TABLE 1 comparison of node bearing capacity calculations

Other parts not described belong to the prior art.

Claims (1)

1. A method for calculating the bearing capacity of a steel pipe K-shaped penetration welding joint with stiffening comprises the following steps:

step 1: determining the smaller value sigma of the pressure stress of the main pipe on two sides of the node and the yield strength f of the steel of the main pipe_yCalculating to obtain an intermediate parameter psi_n；

Intermediate parameter psi_nCalculated by formula (1):

wherein, sigma is the smaller value of the pressure stress of the main pipes at two sides of the node, and when the main pipes at two sides or one side of the node are pulled, 0 is taken;

step 2: determining the diameter d of a pressure branch_cAnd the diameter D of the main pipe, calculating the pipe diameter ratio beta of the pressure branch pipe to the main pipe and the intermediate parameter psi_β；

The tube diameter ratio beta is calculated by the formula (2)To the intermediate parameter psi_βThe following calculation results in:

β＝d_cformula/D (2)

And step 3: based on the thickness T of the main pipe, the gap a between the two branch pipes, the diameter D of the main pipe and the pipe diameter ratio beta, an intermediate parameter psi is obtained through calculation_a；

The intermediate parameter ψ a is calculated by formula (4):

and 4, step 4: based on the included angle theta between the pressure branch pipe and the main pipe_cMain pipe thickness T, intermediate parameter psi_n、ψ_β、ψ_aDesign value f of the main pipe steel strength_mCalculating the contribution term N of the K-shaped stiffening intersecting welding joint bearing capacity without stiffening node part of the pressurized branch pipe_cK；

N_cKCalculated by equation (5):

and 5: nominal length B of stiffening plate based on pressed branch pipe side_cMain pipe diameter D, pressure branch pipe diameter D_cThe included angle theta between the pressure branch pipe and the main pipe_cAnd calculating to obtain the effective length l of the gusset plate on the pressure receiving side_ec；

Effective length l of pressure side gusset plate_ecCalculated by equation (6):

step 6: based on the diameter of the main pipeD, effective length l of pressure side gusset plate_ecDesign value f of steel strength of gusset plate_pThickness T of main pipe, angle theta between pressure branch pipe and main pipe_cThe intermediate parameter psi_nCalculating the contribution term N of the K-shaped gusset plate part with the bearing capacity of the stiffening intersecting welding node_cP；

N_cPCalculated by equations (7) to (9):

wherein A is_cIs the total cross-sectional area of the pressure branch pipe, f_cFor the design value of the strength of the pressed branch pipe,

and

are all intermediate coefficients;

and 7: based on the diameter D of the main pipe, the thickness T of the main pipe and the thickness T of the ring plate_rHeight h of ring plate_rCalculating the contribution term N of the K-shaped annular plate part with the bearing capacity of the stiffening intersecting welding joint_cR；

N_cRCalculated by equation (10):

in the formula, alpha is radian; when the ring plate is a full ring, taking alpha as 1.1 pi;when the ring plates are 1/4 rings and semi-rings, alpha is the radian of the ring plates; when in use

When it is taken

Step 8, based on the K-shaped non-stiffened node part contribution item N with stiffened intersecting welding node bearing capacity_cKK-shaped node plate part contribution item N with stiffening intersecting welding node bearing capacity_cPK-shaped ring plate part contribution item N with stiffening intersecting welding node bearing capacity_cRCalculating the bearing capacity N of the stiffening intersecting welding joint of the K-shaped pressure branch pipe_cKPRThe tension branch pipe has a bearing capacity N of a stiffening intersecting welding joint_tKPR；

Bearing capacity N of penetration welding joint with stiffening rib for K-shaped compressed branch pipe_cKPRThe bearing capacity N of the intersecting welding joint with the stiffening of the tension branch pipe is calculated according to the formula (11)_tKPRCalculated according to equation (12):

N_cKPR＝N_cK+N_cP+N_cRformula (11)

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