국립중앙도서관 "우편 복사 서비스"로 연결 됩니다.
Surface texturing is a representative technology of low friction and wear resistance and is the latest surface treatment technology that processes fine-sized grooves, dimples, or pockets on a lubricating surface. Recently, its application has expanded...
다국어 입력
あ
ぁ
か
が
さ
ざ
た
だ
な
は
ば
ぱ
ま
や
ゃ
ら
わ
ゎ
ん
い
ぃ
き
ぎ
し
じ
ち
ぢ
に
ひ
び
ぴ
み
り
う
ぅ
く
ぐ
す
ず
つ
づ
っ
ぬ
ふ
ぶ
ぷ
む
ゆ
ゅ
る
え
ぇ
け
げ
せ
ぜ
て
で
ね
へ
べ
ぺ
め
れ
お
ぉ
こ
ご
そ
ぞ
と
ど
の
ほ
ぼ
ぽ
も
よ
ょ
ろ
を
ア
ァ
カ
サ
ザ
タ
ダ
ナ
ハ
バ
パ
マ
ヤ
ャ
ラ
ワ
ヮ
ン
イ
ィ
キ
ギ
シ
ジ
チ
ヂ
ニ
ヒ
ビ
ピ
ミ
リ
ウ
ゥ
ク
グ
ス
ズ
ツ
ヅ
ッ
ヌ
フ
ブ
プ
ム
ユ
ュ
ル
エ
ェ
ケ
ゲ
セ
ゼ
テ
デ
ヘ
ベ
ペ
メ
レ
オ
ォ
コ
ゴ
ソ
ゾ
ト
ド
ノ
ホ
ボ
ポ
モ
ヨ
ョ
ロ
ヲ
―
http://chineseinput.net/에서 pinyin(병음)방식으로 중국어를 변환할 수 있습니다.
변환된 중국어를 복사하여 사용하시면 됩니다.
예시)
- 中文 을 입력하시려면 zhongwen을 입력하시고 space를누르시면됩니다.
- 北京 을 입력하시려면 beijing을 입력하시고 space를 누르시면 됩니다.
А
Б
В
Г
Д
Е
Ё
Ж
З
И
Й
К
Л
М
Н
О
П
Р
С
Т
У
Ф
Х
Ц
Ч
Ш
Щ
Ъ
Ы
Ь
Э
Ю
Я
а
б
в
г
д
е
ё
ж
з
и
й
к
л
м
н
о
п
р
с
т
у
ф
х
ц
ч
ш
щ
ъ
ы
ь
э
ю
я
′
″
℃
Å
¢
£
¥
¤
℉
‰
$
%
F
₩
㎕
㎖
㎗
ℓ
㎘
㏄
㎣
㎤
㎥
㎦
㎙
㎚
㎛
㎜
㎝
㎞
㎟
㎠
㎡
㎢
㏊
㎍
㎎
㎏
㏏
㎈
㎉
㏈
㎧
㎨
㎰
㎱
㎲
㎳
㎴
㎵
㎶
㎷
㎸
㎹
㎀
㎁
㎂
㎃
㎄
㎺
㎻
㎽
㎾
㎿
㎐
㎑
㎒
㎓
㎔
Ω
㏀
㏁
㎊
㎋
㎌
㏖
㏅
㎭
㎮
㎯
㏛
㎩
㎪
㎫
㎬
㏝
㏐
㏓
㏃
㏉
㏜
㏆
RISS 인기검색어
https://www.riss.kr/link?id=T16663790
- 저자
-
발행사항
진주 : 경상국립대학교 대학원, 2023
-
학위논문사항
학위논문(석사) -- 경상국립대학교 대학원 , 기계항공공학부 기계공학전공 , 2023. 2
-
발행연도
2023
-
작성언어
한국어
- 주제어
-
발행국(도시)
경상남도
-
기타서명
A Study on the Thermohydrodynamic Lubrication Analysis of Surface-Textured Parallel Thrust Bearing
-
형태사항
ⅷ, 53 p. : 삽화 ; 30 cm
-
일반주기명
경상국립대학교 논문은 저작권에 의해 보호받습니다.
지도교수: 황욱렬 -
UCI식별코드
I804:48003-000000033012
-
소장기관
- 경상국립대학교 도서관
- 경상국립대학교 도서관
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
Surface texturing is a representative technology of low friction and wear resistance and is the latest surface treatment technology that processes fine-sized grooves, dimples, or pockets on a lubricating surface. Recently, its application has expanded widely, including thrust bearings, mechanical seals, piston-ring, and cylinder liners. So far, most of the theoretical studies related to surface texturing have been interpreted as isothermal (ISO) with constant lubricant viscosity. However, when operating the bearing, it is necessary to consider the increase in oil temperature due to the viscous shear and its effect. Maintaining the temperature of the lubricating surface at a constant state is difficult. Therefore, to more accurately predict the lubrication characteristics of parallel thrust bearings, it is necessary to analyze them by applying appropriate temperature boundary conditions to continuity, Navier-Stokes, and energy equations for oil. The problem requires thermohydrodynamic (THD) lubrication analysis that allows the effect of temperature changes, and this thesis uses computational fluid dynamics (CFD) analysis. This thesis presents the results of the effect of temperature boundary conditions and the effect of groove number and depth on the parallel thrust bearing through CFD analysis.
There is the number and groove depth with maximum load-carrying capacity (LCC) for isothermal (ISO) cases and four temperature boundary conditions. The LCC is maximum near the groove depth where the vortex starts to occur, and the THD result is lower than the ISO result. However, the results for the A-A and T-A conditions in the case of deep grooves were more significant than the ISO results. As the number of grooves increases, the frictional force acting on the slider decreases almost linearly except for the A-A condition. In the A-A condition, the effect of the viscosity decrease due to the high temperature was dominant to the friction reduction than the grooves. Flow rate is highest in A-T condition and lowest in T-A condition. In addition, the flow rate was maximized at the groove depth where the LCC was maximum.
The ISO analysis result of the surface textured bearing overestimates the LCC but underestimates the friction reduction. Therefore, THD analysis should be performed with appropriate temperature boundary conditions to derive accurate design specifications. The numerical analysis method and results used in this paper can be applied to improve the lubrication performance of various sliding bearings with surface texture.
In order to derive the optimal texturing specifications with maximum LCC and minimum friction, additional research considering the effects of cavitation, heat transfer to the bearing surface, and deformation of the bearing surface due to generated pressure and temperature is required.
There is the number and groove depth with maximum load-carrying capacity (LCC) for isothermal (ISO) cases and four temperature boundary conditions. The LCC is maximum near the groove depth where the vortex starts to occur, and the THD result is lower than the ISO result. However, the results for the A-A and T-A conditions in the case of deep grooves were more significant than the ISO results. As the number of grooves increases, the frictional force acting on the slider decreases almost linearly except for the A-A condition. In the A-A condition, the effect of the viscosity decrease due to the high temperature was dominant to the friction reduction than the grooves. Flow rate is highest in A-T condition and lowest in T-A condition. In addition, the flow rate was maximized at the groove depth where the LCC was maximum.
The ISO analysis result of the surface textured bearing overestimates the LCC but underestimates the friction reduction. Therefore, THD analysis should be performed with appropriate temperature boundary conditions to derive accurate design specifications. The numerical analysis method and results used in this paper can be applied to improve the lubrication performance of various sliding bearings with surface texture.
In order to derive the optimal texturing specifications with maximum LCC and minimum friction, additional research considering the effects of cavitation, heat transfer to the bearing surface, and deformation of the bearing surface due to generated pressure and temperature is required.
Surface texturing is a representative technology of low friction and wear resistance and is the latest surface treatment technology that processes fine-sized grooves, dimples, or pockets on a lubricating surface. Recently, its application has expanded widely, including thrust bearings, mechanical seals, piston-ring, and cylinder liners. So far, most of the theoretical studies related to surface texturing have been interpreted as isothermal (ISO) with constant lubricant viscosity. However, when operating the bearing, it is necessary to consider the increase in oil temperature due to the viscous shear and its effect. Maintaining the temperature of the lubricating surface at a constant state is difficult. Therefore, to more accurately predict the lubrication characteristics of parallel thrust bearings, it is necessary to analyze them by applying appropriate temperature boundary conditions to continuity, Navier-Stokes, and energy equations for oil. The problem requires thermohydrodynamic (THD) lubrication analysis that allows the effect of temperature changes, and this thesis uses computational fluid dynamics (CFD) analysis. This thesis presents the results of the effect of temperature boundary conditions and the effect of groove number and depth on the parallel thrust bearing through CFD analysis.
There is the number and groove depth with maximum load-carrying capacity (LCC) for isothermal (ISO) cases and four temperature boundary conditions. The LCC is maximum near the groove depth where the vortex starts to occur, and the THD result is lower than the ISO result. However, the results for the A-A and T-A conditions in the case of deep grooves were more significant than the ISO results. As the number of grooves increases, the frictional force acting on the slider decreases almost linearly except for the A-A condition. In the A-A condition, the effect of the viscosity decrease due to the high temperature was dominant to the friction reduction than the grooves. Flow rate is highest in A-T condition and lowest in T-A condition. In addition, the flow rate was maximized at the groove depth where the LCC was maximum.
The ISO analysis result of the surface textured bearing overestimates the LCC but underestimates the friction reduction. Therefore, THD analysis should be performed with appropriate temperature boundary conditions to derive accurate design specifications. The numerical analysis method and results used in this paper can be applied to improve the lubrication performance of various sliding bearings with surface texture.
In order to derive the optimal texturing specifications with maximum LCC and minimum friction, additional research considering the effects of cavitation, heat transfer to the bearing surface, and deformation of the bearing surface due to generated pressure and temperature is required.
목차 (Table of Contents)
- Ⅰ. 서 론 1
- 1.1 Surface texturing 1
- 1.2 문헌고찰 3
- 1.3 논문의 목적 및 구성 4
- Ⅱ. 수치해석 방법 및 모델 5
- Ⅰ. 서 론 1
- 1.1 Surface texturing 1
- 1.2 문헌고찰 3
- 1.3 논문의 목적 및 구성 4
- Ⅱ. 수치해석 방법 및 모델 5
- 2.1 해석모델 5
- 2.2 지배방정식 6
- 2.3 경계조건 8
- 2.4 격자계의 구성 11
- Ⅲ. 결과 및 고찰 12
- 3.1 그루브가 없는 경우 12
- 3.2 그루브 수의 영향 : 등온해석 19
- 3.3 온도경계조건의 영향 24
- 3.4 그루브 깊이의 영향 33
- Ⅳ. 결 론 48
- 참고문헌 50
- 감사의 글 53
분석정보
연관 공개강의(KOCW)
이 자료와 함께 이용한 RISS 자료
나만을 위한 추천자료
