Spatially-resolved velocities of thermally-produced spray droplets using a velocity-divided Abel inversion of photographed streaks

Kawaguchi, Y.; Kobayashi, Nozomi; Yamagata, Yuriko; Miyazaki, Fumihiro; Yamasaki, Masafumi; Muraoka, Katsunori

doi:10.1088/1361-6463/aa87e0

Cited by 4 publications

(6 citation statements)

References 17 publications

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“…( 1). It should be noted that this limit was obtained under the general thermal droplet's condition, 16,17) for instance the droplet's flux of about 6 × 10 18 m −2 •s −1 in Ref. 16, and the ambient light condition in a normal laboratory room.…”

Section: Resultsmentioning

confidence: 82%

“…It should be noted that this limit was obtained under the general thermal droplet's condition, 16,17) for instance the droplet's flux of about 6 × 10 18 m −2 •s −1 in Ref. 16, and the ambient light condition in a normal laboratory room. When the observation area of the spectrometer is continuously filled with radiating bodies, the lower temperature limit is improved much.…”

Section: Resultsmentioning

confidence: 82%

“…where Ið; TÞ is the intensity of radiation emitted at a wavelength λ from a body surface at a temperature of T, "ð; TÞ is the emissivity which is dependent on the material and its surface conditions, such as surface roughness and the degree of oxidation, along with the wavelength and the temperature of the emitting surface, h is the Planck's constant, c is the speed of light, and κ is the Boltzmann constant. In the simple monitoring system, [12][13][14][15][16] the center wavelengths of 650 and 750 nm with a bandwidth of 50 nm each were chosen in order to measure the temperatures. At the same time, the measurement of the velocity was also facilitated by the time of flight (TOF) technique for the droplets simultaneously using the same optical detection system for two pre-determined spatial positions.…”

Section: Experimental Methodsmentioning

confidence: 99%

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Spectroscopic observation of radiation emitted from thermally-produced spray droplets and the resulting temperature determination

Yamagata¹,

Iwasaka

Kawaguchi³

et al. 2018

Jpn. J. Appl. Phys.

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A spectroscopic observation of emitted radiation from spray droplets, to measure the radiation mostly covering the visible region but extending to both near ultraviolet and infrared, was made along the plasma/spray flow from just the downsteam of a gun exit to a position where substrates are usually placed. The results revealed that although plasma radiation from some molecular and atomic lines are superimposed on a continuum background radiation at a position close to the gun exit, these lines almost completely disappear at a distance of more than 50 mm from the gun exit. In addition, the continuum radiation is well represented by the Planck’s formula with the same fitted temperature of 2,750 ± 50 K at all positions. Finally, the wavelength dependencies of the surface emissivity of the droplets, ε(λ), lower the fitted temperatures by about 300 and 500 K, as one adopts the wavelength dependencies of ε(λ) ∝ λ−1 and λ−2, respectively.

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Section: Resultsmentioning

confidence: 82%

Section: Resultsmentioning

confidence: 82%

Section: Experimental Methodsmentioning

confidence: 99%

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Spectroscopic observation of radiation emitted from thermally-produced spray droplets and the resulting temperature determination

Yamagata¹,

Iwasaka

Kawaguchi³

et al. 2018

Jpn. J. Appl. Phys.

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show abstract

“…Table 1 summarizes the measured values of temperatures and velocities. It should be noted that there is an uncertainty of up to 20% overestimate in these temperatures [5] and a 25% underestimate in these velocities [7]. The former overestimates come from uncertainty in the emissivity value of the droplets, and the latter underestimates come from the necessity of subtracting the contributions of low velocity droplets existing at the peripheries of the droplet flow which are inevitably observed for this kind of line-of-sight measurements (this subtraction was not carried out in the values in table 1).…”

Section: Temperatures and Velocities Of Spray Droplets From The Three...mentioning

confidence: 96%

Optical monitoring systems for thermal spray processes: droplets behavior and substrate pre-treatments

Kawaguchi¹,

Kobayashi

Yamagata³

et al. 2017

J. Inst.

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Thermal spray is a technique to form molten droplets using either plasma-or combustionheating, which impinge upon substrates to form coating layers for various purposes, such as anticorrosion and anti-wear layers. Although it is an established technique having a history of more than a century, operations of spray guns together with preparing suitable substrate surfaces for obtaining good coating layers still rely on experienced technicians. Because of the necessity of meeting more and more stringent requirements for coating quality and cost from customers, there has been a strong need to try to monitor spray processes, so as to obtain the best possible spray coating layers. The basic requirements for such monitoring systems are *reasonably cheap, *easy operation for laypersons, *easy access to targets to be investigated, and *an in-situ capability. The purpose of the present work is to provide suitable optical monitoring systems for (1) droplets behavior and (2) substrate pre-treatments. For the former (1), the first result was already presented at the 17th laseraided plasma diagnostics meeting (LAPD17) in 2015 in Sapporo, and the results of its subsequent applications into real spray environments are shown in this article in order to validate the previous proposal. Topic (2) is new in the research program, and the proof-of-principle experiment for the proposed method yielded a favorable result. Based on this positive result, an overall strategy is being planned to fulfill the final objective of the optical monitoring of substrate pre-treatments. Details of these two programs (1) and (2) together with the present status are described. K: Plasma diagnostics -high speed photography; Plasma diagnostics -interferometry, spectroscopy and imaging 1Corresponding author.

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“…From these photos, one sees a clear axi-symmetry of the discharge between the two electrodes. Therefore, the Abel-inversion [9] of the line-of-sight fringe shifts, shown in figure 11, yields the radial information. As described above, the contributions of electron and neutral densities are different for different wavelengths.…”

Section: On a Discharge Plasma In Air (Cfs With Electrical Engineering)mentioning

confidence: 99%

Forty years (1983–2023) with LAPD and for its future evolution

Muraoka

2023

J. Inst.

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This article is divided into two parts; namely, the first part describes how the series of Laser-aided plasma diagnostics (LAPD) symposia was conceived and has gradually evolved into the present form during the past four decades, and the second part shows the main focus of the meetings to gradually converge into the `cross-fertilizations' with other fields of science and engineering as the raison d'etre of the LAPD symposia, which is explained using outputs of mainly from the author's group. It is the author's hope that the next/coming generation will deepen the above second part for the future LAPD symposia to flourish further by eye-opening new developments.

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Spatially-resolved velocities of thermally-produced spray droplets using a velocity-divided Abel inversion of photographed streaks

Cited by 4 publications

References 17 publications

Spectroscopic observation of radiation emitted from thermally-produced spray droplets and the resulting temperature determination

Spectroscopic observation of radiation emitted from thermally-produced spray droplets and the resulting temperature determination

Optical monitoring systems for thermal spray processes: droplets behavior and substrate pre-treatments

Forty years (1983–2023) with LAPD and for its future evolution

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