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Abstract

Water jet-guided laser machining is a new compound machining technology, which has been widely used in many fields due to its better processing effect. In this technology, the coupling of laser beam and micro-water jet directly determines the machining effect, and the prerequisite for successful coupling is the steady flow of the water jet, so ensuring the stability of the micro-water jet is the key to the stable machining of water jet-guided laser. Therefore, it is of great significance to studying the stability of the water fiber-optic in water jet-guided laser processing. In this paper, aiming at the problem that the stability of the water fiber-optic is difficult to control, a finite element model of the water fiber-optic is established. The convection model is vortex gas-phase flow “enveloped” water fiber-optic which is used to explain the interaction mechanism, and the flow field distribution of gas-phase flow and water fiber-optic convection was obtained. The results show that water fiber-optic is refined under the constraint of gas-phase flow, and the maximum processing distance can increase by three times. At the same time, the gas-phase flow can accelerate the removal of processing debris, and the processing accuracy and efficiency are improved.

Keywords

water fiber-optic finite element analysis water jet-guided laser gas-liquid constraints working distance

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References

Zhang

Y N

Qiao

H C

Zhao

J B

, et al. Numerical simulation of water jet-guided laser micromachining of CFRP[J]. Materials Today Communications, 2020,25:1–10.

Rashed

C A A

Romoli

Tantussi

, et al. Water jet guided laser as an alternative to EDM for micro-drilling of fuel injector nozzles: A comparison of machined surfaces[J]. Journal of Manufacturing Processes, 2013, 15(4):524–532.

Adelmann

Ngo

Hellmann

. High aspect ratio cutting of metals using water jet guided laser[J]. Int J Adv Manu Tech 2015, 80(9–12): 2053–2060.

Wang

Yang

L J

Tang

, et al. Laser and water-jet fiber coupling technology for water-jet guided laser micromachining[J]. Advanced Materials Research, 2009, 69-70:29–33.

Synova

Simple Principle[EB/OL].

Zhang

W W

Zhang

X P

, et al. A simple optical coupling method for water-jet guided laser machining system[J]. Applied Mechanics & Materials, 2014, 541-542:774–779.

Sun

Wang

J H

Han

F Z

. Research on water-guided laser coupling technology based on off-axis optical system[J]. Infrared and laser engineering, 2018, 47(12):15–20.

Yang

L J

Wang

, et al. Coupling technology of laser and water beam fiber in water conducting laser micromachining[J]. Optical precision engineering,2008,16(9).

Hock

Adelmann

Hellmann

. Comparative study of remote fiber laser and water-jet guided laser cutting of thin metal sheets[J]. Physics Procedia, 2012, 39:225–231.

10.

Zhang

Y N

Qiao

H C

Zhao

J B

, et al. Research on water jet-guided laser micro-hole machining of 6061 aluminum alloy[J]. 2021.

11.

Kang

Liu

H X

Yang

M G

, et al. Foundation and application of high-pressure water jet technology[M]. China Machine Press,2015.

12.

X Z

Jiang

K Y

Jiang

, et al. Improving the energy distribution of laser processing by micro jet flow guide[J]. Application of laser,2005,35(2).

13.

Liu

Wei

M R

Zhang

, et al. Overview on the development and critical issues of water jet guided laser machining technology[J]. Optics & Laser Technology, 2021, 137:106820.

14.

Lin

S P

Reitz

R D

. Drop and spray formation from a liquid jet[J]. Annual Review of Fluid Mechanic, 1998, 30(1):85.

15.

Chigier

Reitz

R D

. Regimes of jet breakup and breakup mechanisms (physical aspects) [J]. Progress in Astronautics & Aeronautics, 2015, 166.

16.

Lasheras

J C

Hopfinger

E J

. Liquid jet instability and atomization in a coaxial gas stream[J]. Annual Review of Fluid Mechanics, 2000, 32(1):275.

17.

Zhang

G Y

Chao

Zhang

, et al. Simulation and experimental study on light conduction mechanism of water-air Shrinkage Flow[J]. Electromachining and Mould, 2020(1):5.

18.

Cadavid

Wüstenberg

Louis

, et al. Effect of helium atmospheres on abrasive suspension water jets[J]. International Journal of Advanced Manufacturing Technology, 2005, 26(11-12):1246–1254.

19.

Brecher

Janssen

Eckert

, et al. Thermal investigation of interaction between high-power CW-laser radiation and a water-jet[J]. Physics Procedia, 2016, 83:317–327.

20.

F W.

Introduction to air and gas dynamics[M]. Northwestern Polytechnical university press, 2007.

21.

Shen

Z H

. Water jet theory and technology[J]. China Safety Science Journal, 1999.

22.

Koutsourakis

Bartzis

J G

Markatos

N C

. Evaluation of Reynolds stress, k-ε and RNG k-ε turbulence models in street canyon flows using various experimental datasets[J]. Environmental Fluid Mechanics, 2012, 12(4):379–403.

23.

Y K

. The stability of 30-μm-diameter water jet for jet-guided laser machining[J]. International Journal of Advanced Manufacturing Technology, 2015, 78(5–8):939–946.

24.

Couty

Spiegel

Vago

, et al. Laser-induced break-up of water jet waveguide[J]. Experiments in Fluids, 2004, 36(6):919–927.

25.

Chen

. Study on the interaction process and mechanism between high power laser and underwater matter [D]. Nanjing university of science and technology, 2004.

Numerical simulation of the stability of water fiber-optic in water jet-guided laser machining

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