Lampiran A: Gambar Bagian- bagian dari Alat Penukar Kalor Berdasarkan Standar TEMA

Ukuran: px

Mulai penontonan dengan halaman:

Download "Lampiran A: Gambar Bagian- bagian dari Alat Penukar Kalor Berdasarkan Standar TEMA"

Sugiarto Santoso
6 tahun lalu
Tontonan:

1 Lampiran A: Gambar Bagian- bagian dari Alat Penukar Kalor Berdasarkan Standar TEMA (Sumber: Lit. 1 hal. 2)

2 Lampiran B: Tabel Tebal Shell Minimum (Sumber: Lit. 1 hal. 30) Lampiran C: Tabel Diameter Ruang Bebas untuk Selongsong (Sumber: Lit. 1 hal. 30) Lampiran D: Tabel Standar Batang Pengikat (Sumber: Lit. 1 hal. 36)

3 Lampiran E: Tabel Pipa (Sumber: Lit. 31)

4 Lampiran - F: Tabel Flens (Sumber: Lit. 32)

5 Lampiran G: Tabel Laju Pengotoran untuk Fluida (Sumber: Lit. 2)

6 Lampiran H: Konduktivitas Termal Untuk Benda Padat (Sumber: Lit. 4)

7 Lampiran I: Parameter untuk Sifat Gas Buang SolidWorks Flow Simulation Dynamic Viscosity 85 K K K K K K K K K K K K K o C Pa.s o C Pa.s o C Pa.s o C 0, Pa.s o C Pa.s o C Pa.s o C Pa.s o C Pa.s o C Pa.s o C Pa.s o C Pa.s o C Pa.s o C Pa.s Spesific Heat 100 K o C 1031 J/Kg.K 110 K o C 1030 J/Kg.K 120 K o C 1030 J/Kg.K 130 K o C 1030 J/Kg.K 140 K o C 1031 J/Kg.K 150 K o C 1031 J/Kg.K 160 K o C 1032 J/Kg.K 170 K o C 1032 J/Kg.K 180 K o C 1033 J/Kg.K 190 K o C 1034 J/Kg.K 200 K o C 1035 J/Kg.K 210 K o C 1036 J/Kg.K 220 K o C 1037 J/Kg.K 230 K o C 1039 J/Kg.K 240 K o C 1040 J/Kg.K 250 K o C 1042 J/Kg.K 260 K o C 1043 J/Kg.K 270 K o C 1045 J/Kg.K 280 K 6.85 o C 1047 J/Kg.K 290 K o C 1049 J/Kg.K 300 K o C 1051 J/Kg.K 350 K o C 1062 J/Kg.K 400 K o C 1075 J/Kg.K 450 K o C 1089 J/Kg.K 500 K C 1103 J/Kg.K

8 Thermal Conductivity K K K K K K K K K K K K K K K K K K K K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K o C W/m.K

9 Lampiran J: Report untuk Alat Penukar Kalor 1 1 Lintasan Initial Mesh Settings Automatic initial mesh: On Result resolution level: 5 Advanced narrow channel refinement: Off Refinement in solid region: Off INPUT DATA Geometry Resolution Evaluation of minimum gap size: Automatic Evaluation of minimum wall thickness: Automatic Computational Domain Size X min X max Y min Y max Z min Z max m m m m m m Boundary Conditions 2D plane flow At X min At X max At Y min At Y max At Z min At Z max None Default Default Default Default Default Default Physical Features Heat conduction in solids: On Heat conduction in solids only: Off Radiation: Off Time dependent: Off Gravitational effects: Off Flow type: Laminar and turbulent High Mach number flow: Off Humidity: Off

10 Default roughness: 0 micrometer Default outer wall condition: Adiabatic wall Initial Conditions Thermodynamic parameters Static Pressure: Pa Temperature: C Velocity parameters Velocity vector Velocity in X direction: 0 m/s Velocity in Y direction: 0 m/s Velocity in Z direction: 0 m/s Solid parameters Default material: Steel Stainless 321 Initial solid temperature: C Radiation Transparency: Opaque Turbulence parameters Turbulence intensity and length Intensity: 2.00 % Length: m Material Settings Fluids Flue Gas Water Solids Steel Stainless 321 Copper Insulator Fluid Subdomains Fluid Subdomain 1 Thermodynamic Parameters Static Pressure: Pa Temperature: C Velocity Parameters Velocity in X direction: 0 m/s Velocity in Y direction: 0 m/s Velocity in Z direction: 0 m/s Turbulence parameters type: Turbulence intensity and length Intensity 2.00 % Length m Flow type Laminar and Turbulent Humidity Off Default fluid type Gas Fluids Flue Gas Faces Face<1>@LID1-1 Coordinate system Face Coordinate System Reference axis X Fluid Subdomain 2

11 Thermodynamic Parameters Static Pressure: Pa Temperature: C Velocity Parameters Velocity in X direction: 0 m/s Velocity in Y direction: 0 m/s Velocity in Z direction: 0 m/s Turbulence parameters type: Turbulence intensity and length Intensity 2.00 % Length m Flow type Laminar and Turbulent Cavitation Off Default fluid type Liquid Fluids Water Faces Face<1>@LID4-1 Coordinate system Face Coordinate System Reference axis X Solid Materials Copper Solid Material 1 Components Solid substance Radiation Transparency TUBE-1@APK 1-1 PASS Copper Opaque Steel Stainless 321 Solid Material 1 Components cover-1@apk 1-1 PASS SHELL-1@APK 1-1 PASS BAFFLE-1@APK 1-1 PASS TUBESHEET-2@APK 1-1 PASS cover-2@apk 1-1 PASS TUBESHEET-1@APK 1-1 PASS Solid substance Steel Stainless 321 Radiation Transparency Opaque Insulator Solid Material 1 Components Solid substance Radiation Transparency PACKING-2@APK 1-1 PASS PACKING-3@APK 1-1 PASS PACKING-4@APK 1-1 PASS PACKING-1@APK 1-1 PASS Insulator Opaque Boundary Conditions Inlet Mass Flow Gas Buang Type Inlet Mass Flow Faces Face <1> Coordinate system Face Coordinate System

12 Reference axis Flow parameters Thermodynamic parameters X Flow vectors direction: Normal to face Mass flow rate normal to face: kg/s Fully developed flow: Yes Approximate pressure: Pa Temperature: C Static Pressure Gas Buang Type Static Pressure Faces Face <1> Coordinate system Face Coordinate System Reference axis X Thermodynamic parameters Static pressure: Pa Temperature: C Turbulence parameters Turbulence intensity and length Intensity: 2.00 % Length: m Boundary layer parameters Boundary layer type: Turbulent Inlet Mass Flow Air Type Inlet Mass Flow Faces Face <1> Coordinate system Face Coordinate System Reference axis X Flow parameters Flow vectors direction: Normal to face Mass flow rate normal to face: kg/s Fully developed flow: Yes Thermodynamic parameters Temperature: C Static Pressure Air Type Static Pressure Faces Face <1> Coordinate system Face Coordinate System Reference axis X Thermodynamic parameters Static pressure: Pa Temperature: C Turbulence parameters Turbulence intensity and length Intensity: 2.00 % Length: m Boundary layer parameters Boundary layer type: Turbulent Goals Global Goals GG Max Temperature of Fluid 1 Type Global Goal

13 Goal type Calculate Coordinate system Use in convergence Temperature of Fluid Maximum value Global coordinate system On Calculation Control Options Finish Conditions Finish conditions If one is satisfied Maximum travels Goals convergence Analysis interval: Solver Refinement Refinement: Disabled Results Saving Save before refinement On Advanced Control Options Flow Freezing Flow freezing strategy Disabled

14 Lampiran J: Gambar Desain Alat Penukar Kalor 1. Penutup Penutup Depan APK 1-1 Pass Penutup Belakang APK 1-1 Pass Penutup Depan APK 1-2 Pass Penutup Belakang APK 1-2 Pass

15 Penutup Depan APK 1-4 Pass Penutup Belakang APK 1-4 Pass 2. Sekat (a) (b) (c) Gambar: Penutup Pelat, (a) 1-1 APK Pass, (b) 1 2 Pass, (c) 1 4 Pass 3. Penutup pelat Penutup pelat dan paking memiliki bentuk geometri yang sama hanya berbeda ketetebalan dan jenis materialnya. (a) (b) (c) Gambar: Penutup Pelat, (a) 1-1 APK Pass, (b) 1 2 Pass, (c) 1 4 Pass

16 Lampiran H: Grafik Hubungan Hasil Perhitungan dan Simulasi CFD Gambar: Hubungan penurunan tekanan pada sisi tabung terhadap jumlah pass Gambar: Hubungan penurunan tekanan pada sisi selongsong (Metode Kern) terhadap jumlah pass

17 Gambar: Hubungan penurunan tekanan pada sisi selongsong (Metode Bell Dellaware) terhadap jumlah pass Gambar: Hubungan suhu keluar pada sisi tabung terhadap jumlah pass

18 Gambar: Hubungan suhu keluar pada sisi selongsong terhadap jumlah pass Gambar: Hubungan efektivitas alat penukar kalor (Metode Kern) terhadap Pjumlah pass

19 Gambar: Hubungan efektivitas alat penukar kalor (Metode Bell Dellaware) terhadap jumlah pass

dokumen-dokumen yang mirip

INVESTIGASI KARAKTERISTIK PERPINDAHAN PANAS PADA DESAIN HELICAL BAFFLE PENUKAR PANAS TIPE SHELL AND TUBE BERBASIS COMPUTATIONAL FLUID DYNAMICS (CFD)

INVESTIGASI KARAKTERISTIK PERPINDAHAN PANAS PADA DESAIN HELICAL BAFFLE PENUKAR PANAS TIPE SHELL AND TUBE BERBASIS COMPUTATIONAL FLUID DYNAMICS (CFD) Mirza Quanta Ahady Husainiy 2408100023 Dosen Pembimbing