Temperature prediction based control method for precise forming of laser cladding thin-walled workpiece

A technology of laser cladding and control methods, which is applied in the direction of additive manufacturing, process efficiency improvement, coating, etc., can solve the problem of thin wall thickness instability, etc., and achieve the effect of stable thickness and steady increase in height

Active Publication Date: 2018-11-30
NORTHEASTERN UNIV LIAONING
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Problems solved by technology

[0005] In the existing method, the power of the laser is adjusted according to the height of the cladding layer to achieve the purpose of stabilizing the growth of the cladding layer. However, if the laser power is judged only by the height, the thickness of the thin wall will become unstable.

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  • Temperature prediction based control method for precise forming of laser cladding thin-walled workpiece
  • Temperature prediction based control method for precise forming of laser cladding thin-walled workpiece
  • Temperature prediction based control method for precise forming of laser cladding thin-walled workpiece

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Embodiment Construction

[0020] The specific implementation manners of the present invention will be further described in detail below in conjunction with the accompanying drawings and embodiments. The following examples are used to illustrate the present invention, but are not intended to limit the scope of the present invention.

[0021] The method of this embodiment is as follows:

[0022] Step 1: According to the response surface method, conduct a single-pass cladding experiment, and obtain the regression model of the influence of powder feeding speed, scanning speed, laser power and substrate temperature on the parameters of the single-pass cladding layer, such as melting width, melting height and aspect ratio;

[0023] The equipment used in the examples includes a KUKA robotic arm, a coaxial powder feeding laser head, a fiber laser and a turntable powder feeder. These devices have established a communication relationship with the KUKA robot control cabinet, and these devices can be called throu...

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Abstract

The invention discloses a temperature prediction based control method for precise forming of a laser cladding thin-walled workpiece, and relates to the field of laser cladding forming. The method comprises the three steps that firstly, a regression model of the influences of the powder feed speed, the scanning speed, the laser power and the substrate temperature on the weld width, weld height andaspect ratio parameters of single-channel cladding layers is set up through a response surface method; secondly, a theoretical prediction model of the relation between the cladding temperature and thenumber of the cladding layers during multi-layer cladding is set up; and thirdly, through combination of the regression model, the target weld width and weld height are adopted as compensation targets, the actual forming size is subjected to compensation, and a proper power adjusting curve is determined. According to the method, in the cladding process, the thickness of the thin-walled workpieceis stable, the height is increased stably, the condition of preset programming is met, and finally the thin-walled workpiece high in cladding quality is obtained.

Description

technical field [0001] The invention belongs to the field of laser cladding forming, in particular to a control method for precise forming of laser cladding thin-walled parts based on temperature prediction. Background technique [0002] Laser cladding forming (LCF) is a laser rapid prototyping technology developed in recent years. This technology combines the characteristics of rapid prototyping and laser cladding surface strengthening technology, and can be widely used in the direct forming and repair of complex thin-walled parts, and has a very broad application prospect. The use of laser cladding forming technology has unique advantages such as processing complex parts, high degree of flexibility and close-range forming. [0003] In particular, laser cladding forming technology has more obvious advantages in processing thin-walled parts. When processing thin-walled parts such as aeroengine impeller blades by traditional subtractive methods, there are disadvantages such...

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): B22F3/105C23C24/10B33Y10/00B33Y50/02
CPCC23C24/103B33Y10/00B33Y50/02B22F10/00B22F10/25B22F10/80Y02P10/25
Inventor 袁存涛朱立达王书豪陈雪松杨康康张海权
Owner NORTHEASTERN UNIV LIAONING
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