CN112059386A

CN112059386A - Method for controlling fuse deposition molten pool state

Info

Publication number: CN112059386A
Application number: CN202010938168.2A
Authority: CN
Inventors: 洪波; 林健; 熊昊; 向垂悦; 刘锦
Original assignee: Xiangtan University
Current assignee: Xiangtan University
Priority date: 2020-09-08
Filing date: 2020-09-08
Publication date: 2020-12-11
Anticipated expiration: 2040-09-08
Also published as: CN112059386B

Abstract

The invention discloses a method for controlling the state of a fuse wire deposition molten pool, which can be applied to the additive manufacturing of magnetic control plasma welding and has the advantages of improving the internal thermal circulation of the molten pool, reducing the heat accumulation in the welding process, preventing the collapse of a cladding layer, avoiding the uneven structure, ensuring the hardness and the forming quality and the like; the technical scheme is as follows: for area greater than preset minimum threshold S₀The high-temperature region of (2) is classified: the high-temperature area with a regular shape directly takes the outer contour line as a path, and the arc oscillation is controlled by a magnetic field to avoid the winding of the high-temperature area; the high-temperature area with the irregular shape is segmented by adopting a fuzzy partitioning method and then is avoided winding along the non-intersecting part contour as a path; for minimum distances less than a preset minimum threshold L₀The adaptive curvature radius is adopted in the plurality of high-temperature areas, and the arc transition mode is adopted to avoid winding according to the outline, so that the phenomenon that the electric arc lingers in the dense outline for a long time to cause heat accumulation is avoided.

Description

Method for controlling fuse deposition molten pool state

Technical Field

The invention relates to the field of magnetic control plasma arc fuse wire additive manufacturing, in particular to a method for controlling the state of a fuse wire deposition molten pool.

Background

Additive manufacturing is an advanced manufacturing technology developed in the middle of the 80's of the 20 th century, and the technology directly manufactures solid parts by adopting a method of material layer-by-layer accumulation according to three-dimensional model data of the parts by taking laser, electron beams, electric arcs and the like as heat sources. According to different specific forming processes, selective laser Sintering (SLM), Laser Melting Deposition (LMD), Plasma Arc Additive Manufacturing (PAAM), cold metal transition forming (CMT), selective electron beam melting (EBSM), and the like are common. Compared with the traditional machining technology, the metal additive manufacturing can reduce the working procedures, shorten the manufacturing period and save raw materials, is a new near-net-shape manufacturing method and has remarkable advantages for manufacturing complex structural parts.

In the additive manufacturing process, the control of the interlayer temperature has a crucial influence on the welding quality and the forming condition. The heat can constantly produce, spread along with the increase of the welding number of piles in welding process, and different figurative components can have different heat accumulation effects at the in-process that takes shape, after the heat accumulation to certain degree, appear that the tissue is inhomogeneous, the tissue is thick and serious composition segregation, and cladding layer edge can take place phenomenons such as collapse, can influence the manufacturing accuracy and the product quality of additive manufacturing.

Wanyuwei et al, a national energy-based wall power plant, proposes to control the magnitude of the arc welding thermal efficiency η by adjusting the welding current and the arc voltage, and at the same time, to control the welding speed and the like to control the heat input during the welding process. However, the adjustment of current and voltage may not only control the heat input but also have adverse effects on the welding quality, and may cause defects such as too narrow a melt width and insufficient melt depth, and the voltage and current cannot be modified in real time in the additive manufacturing process.

Chinese patent CN108907188 discloses a temperature control device for additive manufacturing and a control method thereof, wherein a front preheating component is arranged at the front end of a printing head, and a rear cooling component is arranged at the rear end of the printing head, so that the phenomena of uneven structure and the like of a formed part due to large temperature difference are reduced, the formed part can be rapidly cooled by cooling gas after printing is finished, and the situation that the formed part is oxidized by ambient air due to high temperature is avoided. However, the essence of the invention is that only a preheating device and a cooling part are additionally arranged, and the cooling part adopts a traditional external cooling mode of cooling by cooling gas, so that the temperature can not be adjusted from the inside, and the heat circulation in the molten pool is not improved.

Based on the defects, the invention designs the method for controlling the state of the fuse wire deposition molten pool in order to effectively solve the problems of poor heat dissipation condition of the molten pool, collapse, reduced hardness, poor molding quality and the like caused by heat accumulation in the process of additive manufacturing of the magnetic control plasma fuse wire. The method controls the swing of the magnetic field by identifying and classifying the high-temperature area of the molten pool, improves the thermal cycle of the molten pool, prevents heat accumulation and ensures the consistency of hardness and forming quality.

Disclosure of Invention

The invention provides a method for controlling the state of a fuse wire deposition molten pool, which solves the problems that a cladding layer collapses, the local structure is thick and hard, the molding quality is poor and the like due to local heat accumulation caused by uneven heat distribution in the cladding process.

The technical scheme adopted by the invention aiming at the problems is as follows: firstly, a high temperature threshold value T is set according to the welding process₁And a minimum radius R of a high temperature region₀The infrared scanning thermodetector scans and measures the temperature of the molten pool in real time and measures the temperature of the molten pool higher than T₁Is punctuated and noted as { A₁,A₂,., Ax }, automatically establishing a plane rectangular coordinate system, and projecting the scanned high-temperature region boundary into the coordinate system.

Carrying out data preprocessing on the boundary of the high-temperature area, firstly carrying out smooth processing to eliminate sharp inflection points, and secondly carrying out data preprocessing on the boundary of the high-temperature area when the curvature radius is smaller than a preset minimum value R_MINThe positions and the positions with complex shapes are subjected to fuzzy processing, namely, one or more sections of circular arcs with large curvature radius are used for replacing, and the boundary curve after pretreatment is subjected to least square fitting. The high temperature region is divided into two types according to the shape: the shape is regular and approximately circular and irregular; judging the high-temperature area by least square fitting, and presetting a fitting time threshold N and a fitting minimum distance threshold L₀If the fitting result is less than the fitting minimum distance threshold L₀And if the fitting times are less than N, the shape is judged to be regular and approximate to a circle, and if the fitting times are more than N, the shape is judged to be irregular.

Utilizing a least square method to fit out the boundary of the high-temperature area, calculating the centroid and taking the average value R of the maximum radius and the minimum radius_XRadius of high temperature zone, if there is a high temperature spot and high temperature zoneRadius less than R₀Discarding the high temperature region; radius greater than R for region₀Is represented by R_XMake a circle O for the radius_XAnd the first point of intersection of the circle and the welding track is F, the original swing track and the winding-avoiding track of the electric arc are processed through a computer, the winding-avoiding track is converted into the frequency and the amplitude of alternating current, the frequency and the amplitude of an excitation power supply are adjusted from the point F, and the transverse magnetic field swing in the XY direction in the horizontal plane is controlled to synthesize the arc-shaped swing of the electric arc, so that the electric arc bypasses a high-temperature area.

And carrying out fuzzy partition processing on the high-temperature area with an irregular shape, selecting one or more simple regular graphs with similar shapes for substitution according to the fitting result of the Nth time, and further abandoning dead corners or small areas left after division, so that a plurality of tangent or intersected high-temperature areas with regular shapes can be obtained, controlling a magnetic field to enable the electric arc to avoid winding according to the track of the non-intersected part, and carrying out transition in a mode of circular arc transition (the minimum transition radius is preset in advance) at the tangent and intersected positions, so that the phenomenon that the electric arc lingers in the dense contour position for too long time to cause excessive heat input can be avoided, and the accuracy requirement on electric arc control is reduced.

When the distribution of a plurality of high-temperature areas is close, the minimum distance judgment is carried out along the swing track of the electric arc, and if the minimum distance is smaller than a preset value L₁And determining the transition curvature radius of the arc transition according to the curvature radius of the intersection point of the contour and the swing track according to the intersection processing, and performing the transition in an arc transition mode, so that the heat input can be reduced, the swing stroke of the electric arc can be reduced, the efficiency is improved, and the requirement on the swing precision of the electric arc can be reduced. If the distance is greater than the preset value L₁And performing detour according to the original contour track, and performing rounding treatment at the intersection of the contour and the swing track.

Drawings

FIG. 1 is a flow chart of bypass of a single high temperature zone

FIG. 2 is a flow chart of bypass of multiple high temperature zones

FIG. 3 is a schematic view of the outline processing of the high temperature region with regular shape

FIG. 4 is a schematic view of the outline processing of the irregularly shaped high-temperature region

FIG. 5 is a schematic diagram of a plurality of adjacent or tangent high temperature zone bypass paths

Detailed description of the preferred embodiment

Example 1: referring to fig. 1 and 3, the technical solution adopted by the present invention to solve the above problems is as follows: firstly, a high temperature threshold value T is set according to the welding process₁And a minimum radius R of a high temperature region₀And minimum area S of high temperature region_MINAccording to the temperature measurement result of real-time scanning of the infrared scanning thermometer on the molten pool, for the temperature higher than T₁Is punctuated and noted as { A₁,A₂,...,A_XAnd automatically establishing a plane rectangular coordinate system by the central processing unit, and projecting the scanned boundary line of the high-temperature area into the coordinate system.

Performing data preprocessing on the boundary of the high-temperature region, firstly performing smooth processing, identifying sharp inflection points by images, eliminating the sharp inflection points, and respectively spacing a distance C in a plane rectangular coordinate system₀And (presetting) straight lines parallel to the X axis and the Y axis, wherein the straight lines and the contour line of the high-temperature region have intersection points, and when the number of the intersection points on each straight line is more than or equal to 3, the rest points except the first and the last points are judged to be positions with complex shapes. Presetting a minimum value R of the curvature radius according to actual process requirements_MIN，

S is the arc length of the fixed point on the curve, alpha is the tangential angle, K is the curvature,

for positions R with radius of curvature smaller than_MINAnd the position with complex shape adopts a fuzzy processing method, namely, one or more sections of circular arcs with large curvature radius are used for replacing, and the pre-treatment is carried outAnd fitting the processed boundary curve by adopting a curve fitting method of closed discrete points.

The fitting function is expressed as follows:

in the formula: a (x) ═ a₁(x),a₂(x),···,a_m(x))^TIs a coefficient vector;

p(x)＝(p₁(x),p₂(x),···,p_m(x))^Tfor the basis functions, polynomial bases are typically chosen.

Linear base: p (x) ═ (1, x, y)^T,m＝3

Secondary group: p (x) ═ 1, x, y, x²,xy,y²)^T,m＝6

Defining discrete weights L of an approximation function₂Norm is:

the matrix form is:

J＝(pa(x)-u)^TW(x)(pa(x)-u)

in the formula: u ═ u (x)₁),u(x₂),···u(x_N))^T

W(x)＝diag(ω₁(s),ω₂(s),…,ω_N(s))

Based on the principle of least square, the method comprises the following steps:

a(x)＝A^-1(x)B(x)u

A(x)＝P^TW(x)P,B(x)＝P^TW(x)

the fitting process defines X between two adjacent discrete points Xi and Xi +1, takes one point (X _ val, y _ val) on a straight line passing through two points, makes X _ val equal to X, and supports the weight ω (s (X _ val) of each point in the domain_i) Determined by the distance of the point to each point, and:

in the formula: i, j ═ 1, 2, …, N, k > 1.

In the formula: α is 0.5.

The high-temperature area is divided into two types according to the shape, namely the shape is regular and approximately circular and the shape is irregular: judging the high-temperature area by using the fitting result, and presetting a fitting time threshold N and a fitting minimum distance threshold L₀If the fitting result is less than the fitting minimum distance threshold L₀And if the fitting times are less than N, the shape is judged to be regular and approximate to a circle, and if the fitting times are more than N, the shape is judged to be irregular.

Calculating the centroid of the boundary curve of the high temperature region and taking the average value R of the maximum radius and the minimum radius_XThe radius of the high temperature region is less than or equal to R if there is one₀Discarding the high temperature region; radius greater than R for region₀Is represented by R_XMake a circle O for the radius_XThe first point of intersection of the circle and the welding track is F, the original swing track and the winding-avoiding track of the electric arc are processed through a computer, the winding-avoiding track is converted into the frequency and the amplitude of alternating current, the frequency and the amplitude of an excitation power supply are adjusted from the point F, the XY-direction magnetic field swing in a horizontal plane is controlled to synthesize the arc-shaped swing of the electric arc, and the electric arc is wound aroundAnd opening a high-temperature area.

Excitation power supply output frequency

I_INIs the pin current, and C is the pin-connected capacitance.

The specific output voltage is

V_OUTFor outputting an analog voltage, V, of the D/A conversion chip_REFS1 is the converted value of the digital frequency obtained by the cpu (range Ox 000-OxFFF),

and F is the value of the digital frequency obtained by the central processing unit.

F_y＝Isinα·cosβ

F_y'＝Icosα·Bsinβ

F₁＝K₁Ie_y

Taking current I at any place of the arc, then I_X，I_ZThe components of the magnetic field B in the transverse and axial directions, respectively, are also decomposed into B_X，I_ZForms an angle of alpha with I, B_ZForming an angle beta with B. The axial force of the magnetic field received by the unit arc column is F_YAnd a transverse force of F_Y’，K₁Denotes the coefficient of restorability, e_yRepresenting the length of the lateral excursion of the arc end, with an aerodynamic drag of F_S

F_y+F_y'＝F_S+F₁

Namely, it is

Example 2: referring to fig. 1 and 4, for a high-temperature area with an irregular shape, fuzzy partition processing is performed, one or more simple regular graphs with similar shapes are selected for substitution according to the fitting result of the Nth time, and further, some dead corners or the remaining area after segmentation is smaller than a preset value S_MINThe narrow area is abandoned, so that a plurality of tangent or intersected high-temperature areas with regular shapes can be obtained, the magnetic field is controlled to enable the electric arc to avoid winding according to the track of the non-intersected part, and arc transition (the minimum transition radius is preset in advance) is adopted at the tangent and intersected positions to carry out transition, so that excessive heat input caused by overlong time when the electric arc wanders at the dense contour position can be avoided, and the accuracy requirement on electric arc control is lowered.

Example 3: referring to fig. 2 and 5, when the distribution of the high-temperature areas is similar, the minimum distance is judged along the swing track of the arc, and if the minimum distance is smaller than a preset value L₀And determining the transition curvature radius of the transition arc according to the curvature radius of the intersection point of the contour and the swing track according to intersection processing, and performing transition in an arc transition mode, so that the heat input can be reduced, the swing stroke of the electric arc can be reduced, the efficiency is improved, and the requirement on the swing precision of the electric arc can be reduced. If the distance is greater than the preset value L₀And performing detour according to the original contour track, and performing rounding treatment at the intersection of the contour and the swing track.

The above description is only a few specific embodiments of the present invention, and it is obvious that modifications or specific substitutions by anyone skilled in the art under the technical scheme of the present invention are included in the scope of the present invention defined by the claims.

Claims

1. A method for controlling the state of a fuse deposition molten pool is characterized in that in the process of additive manufacturing of a magnetic control plasma arc fuse, a high-temperature area is prevented from being wound by controlling a magnetic field adaptive swing electric arc, heat distribution is controlled, the internal heat circulation of the molten pool is improved, the defects of collapse and the like of the edge of a cladding layer due to heat accumulation are prevented, and the forming quality in the process of additive manufacturing is improved.

2. The method of claim 1, wherein the infrared scanning thermometer measures the temperature of the molten bath by scanning in real time, and a temperature threshold T is preset₁For higher than T₁And the position with regular shape takes the point as the center of a circle and the average value R of the maximum radius and the minimum radius_XThe circle with radius is a high-temperature area, the first point of the intersection of the high-temperature area and the arc swinging track is F, the arc swinging is synthesized by controlling the transverse swinging and the longitudinal swinging of the magnetic field from the F point, the arc bypasses the high-temperature area, the high-temperature area with the irregular shape is processed by adopting a fuzzy partition method, the complex shape is divided into a plurality of simple geometric figures with regular shapes, and the arc swings according to the outer contour of the non-overlapped part to avoid the winding.

3. The method of claim 2, wherein the arc swinging path is planned when the arc swinging path meets a plurality of high temperature areas with similar and irregular distribution, if there is no intersection between circles in the high temperature areas and the shortest distance along the arc swinging direction is greater than the predetermined minimum value L₀When the arc is not wound, arc winding is carried out in a high-temperature area according to the original swing track; if the distance between the high temperature regions is less than L₀Or when the arc is intersected and tangent, avoiding winding according to the arc of the non-intersected part, and adopting arc smoothing treatment at the intersection point or tangent point to reduce excessive heat input caused by long time of wandering the arc at the dense outline position.