Design of agitated Heat transfer vessel
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Transcript of Design of agitated Heat transfer vessel
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Design of agitated Design of agitated Heat transfer vesselHeat transfer vessel
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GROUP MEMBERSGROUP MEMBERS SABA 06-CHEM-02SABA 06-CHEM-02FARIHA 06-CHEM-16FARIHA 06-CHEM-16SHAZIA 06-CHEM-38SHAZIA 06-CHEM-38
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Dual ShaftDual Shaft Paste MixerPaste Mixer The Dual Shaft Mixer The Dual Shaft Mixer
includes an Anchor agitator includes an Anchor agitator and a High Speed Disperser. and a High Speed Disperser. The anchor feeds product The anchor feeds product into the high speed disperser into the high speed disperser blade and ensures that the blade and ensures that the mixture is constantly in mixture is constantly in motion. The anchor can be motion. The anchor can be provided with scrapers to provided with scrapers to remove materials from the remove materials from the interior vessel walls to interior vessel walls to enhance the heat transfer enhance the heat transfer capabilities of the mixer. capabilities of the mixer. Both agitators are available Both agitators are available for variable speed operation for variable speed operation
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Jacked and coil heat transfer Jacked and coil heat transfer agitator vesselagitator vessel
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Heat transfer coil in side Heat transfer coil in side vesselvessel
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Use of bafflesUse of baffles
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ApplicationsApplications Mixing tanks are typically used in the Mixing tanks are typically used in the
production of viscous fluids such as production of viscous fluids such as petroleum, plastics, paints, paper, cosmetics, petroleum, plastics, paints, paper, cosmetics, and food. The mechanical agitation of fluid in and food. The mechanical agitation of fluid in these vessels can significantly increase the these vessels can significantly increase the rate of heat transfer between the process rate of heat transfer between the process and cooling fluids. Since the 1950s, a and cooling fluids. Since the 1950s, a number of authors have explored heat number of authors have explored heat transfer for Newtonian fluids in a variety of transfer for Newtonian fluids in a variety of agitated vessel configurations. There has agitated vessel configurations. There has been a limited amount of research been a limited amount of research performed, however, for heat transfer to non-performed, however, for heat transfer to non-Newtonian (power law) fluids.Newtonian (power law) fluids.
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chemical, food, drugs dyes and chemical, food, drugs dyes and other industries other industries
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Use for Pharmaceutical Use for Pharmaceutical Application Application
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used in chemical and pharmaceutical used in chemical and pharmaceutical industriesindustries
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Petro-Chemical, Polymers,Coatings & Petro-Chemical, Polymers,Coatings & Adhesives ,Agricultural & General Adhesives ,Agricultural & General
Chemicals,Plastics&Rubber ,Food & Beverage Chemicals,Plastics&Rubber ,Food & Beverage Industry.Industry.
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Homogeneous Batch/Semi-Homogeneous Batch/Semi-batch Reactionsbatch Reactions
Homogeneous batch/semi-batch are Homogeneous batch/semi-batch are the most common reaction type. the most common reaction type. They can be as simple as adding They can be as simple as adding measured quantities of two or more measured quantities of two or more reactants to a vessel and mixing. reactants to a vessel and mixing. Heat is normally removed or added Heat is normally removed or added through a jacket, heating mantle or through a jacket, heating mantle or external heat exchanger external heat exchanger
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STATEMENTSTATEMENT Calculate the time required to heat Calculate the time required to heat
1268 gal. of liquid from 801268 gal. of liquid from 80OOF to 180F to 180OOF F in a jacketed, agitated vessel in a jacketed, agitated vessel conforming to standard configuration conforming to standard configuration as shown in the figure. The vessel is as shown in the figure. The vessel is assumed to be clean, free of fouling assumed to be clean, free of fouling films and heated with 212films and heated with 212OOF steam.F steam.
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Data GivenData Given
Liquid Properties:Liquid Properties:Cp = 0.6 Btu/(lb) (Cp = 0.6 Btu/(lb) (OOF)F)k= 0.1Btu/(hr)(sq.ft)(k= 0.1Btu/(hr)(sq.ft)(OOF/ft)F/ft)μμ= 1000cp (at80F)= 1000cp (at80F)ρρ=60lb/ft3 = 8.02lb/gal=60lb/ft3 = 8.02lb/galCp,k and Cp,k and ρρ are assumed to be constant are assumed to be constant
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Steam properties:Steam properties:hhss=1000 Btu/(hr)(sq.ft)(=1000 Btu/(hr)(sq.ft)(OOF)F)Vessel Properties:Vessel Properties:Wall thickness= 0.125 inWall thickness= 0.125 inK of vessel = 9.4 Btu/(hr)(sq.ft)(K of vessel = 9.4 Btu/(hr)(sq.ft)(OOF/ft)F/ft)
Eq used for calculating heat transfer Eq used for calculating heat transfer coefficientcoefficient
NNNUNU = 0.73(N = 0.73(NRERE))0.650.65(N(NPRPR))0.33(0.33(μμww/ / μμbb))0.140.14
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STEP 1:STEP 1: Diameter of the vessel DDiameter of the vessel DTT =6 ft. =6 ft.6-ft diameter agitated vessel conforming to 6-ft diameter agitated vessel conforming to
standard configuration as shown in the standard configuration as shown in the figure. The vessel is equipped with the 2 ft figure. The vessel is equipped with the 2 ft diameter 6-blade, flat-blade turbine diameter 6-blade, flat-blade turbine impeller running at 100 rpm.impeller running at 100 rpm.
Diameter of impeller = 2ftDiameter of impeller = 2ft Impeller blade width=0.5 ftImpeller blade width=0.5 ft Impeller blade height=0.4 ftImpeller blade height=0.4 ft Baffle width=0.6 ftBaffle width=0.6 ft
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STEP 2:STEP 2:Inside area of the vessel = Inside area of the vessel = ππDL (L=D)DL (L=D) = 3.14(6)(6)= 3.14(6)(6) = 113 ft2= 113 ft2
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STEP 3:STEP 3: Reynolds number evaluation at Reynolds number evaluation at 80F,130F,180F by using,80F,130F,180F by using, NNRERE = = ρρN DN Dii
22//μμHere, we assume density to be constantHere, we assume density to be constantover the temperature range.over the temperature range.Viscosity values at different Viscosity values at different
temperatures is;temperatures is; μμ((80F80F) = 1000cp (from table)) = 1000cp (from table) μμ((130F130F) = 270 cp) = 270 cp μμ((130F130F) = 84cp) = 84cp
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Diameter of impeller, DDiameter of impeller, Dii = 2 ft = 2 ftFrom these values , the Reynolds From these values , the Reynolds
number is,number is, NNRERE(80F) = (60)(6000)(4)/(2420)(80F) = (60)(6000)(4)/(2420) = 595= 595 NNRERE(130F)= 2200(130F)= 2200 NNRERE (130F)=7080 (130F)=7080
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STEP 4:STEP 4: The Prandtl number calculations at The Prandtl number calculations at
80F,130F,180F are,80F,130F,180F are, NNPRPR = C = CPP μμ /k /k
NNPR PR (80F) = (0.6)(2420)/(0.1)(80F) = (0.6)(2420)/(0.1) = 14500= 14500 NNPR PR (130F) = 3920(130F) = 3920 NNPR PR (180F) = 1220(180F) = 1220
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STEP 5:STEP 5: Approximate the value of Approximate the value of
inside heat transfer coefficient from inside heat transfer coefficient from given equation;given equation;
NNNUNU = h = hii D DTT/k = 0.73(N/k = 0.73(NRERE))0.650.65(N(NPRPR))0.330.33
substitutingsubstituting the appropriate values the appropriate values into this relationship gives:into this relationship gives:
hhii(80F) =18.4 Btu/(F) (hr) (sq.ft)(80F) =18.4 Btu/(F) (hr) (sq.ft)hhii(130F) =27.6 Btu/(F) (hr) (sq.ft)(130F) =27.6 Btu/(F) (hr) (sq.ft)hhii(180F) =40.4 Btu/(F) (hr) (sq.ft)(180F) =40.4 Btu/(F) (hr) (sq.ft)
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STEP 6:STEP 6: The wall temperature from the above The wall temperature from the above
heat transfer coefficients are heat transfer coefficients are calculated and used to evaluate the calculated and used to evaluate the viscosity of liquid at vessel wall viscosity of liquid at vessel wall
The wall temperature is estimated The wall temperature is estimated from the approximate equation:from the approximate equation:
TTWW = T = TSS – [(T – [(TSS -T -TBB)/1+(hsA)/1+(hsAOO/hiA/hiAii)])] here, Ahere, AOO= A= Aii
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Solving wall temperature Solving wall temperature TTW W (at T(at TB B = 80F) = 209.6 F= 80F) = 209.6 FTTW W (at T(at TB B = 130F) = 209.8 F= 130F) = 209.8 FTTW W (at T(at TB B = 180F) = 210.7 F= 180F) = 210.7 F
Viscosity values at different Viscosity values at different temperatures is;temperatures is;
μμ((209.6F209.6F) = 47cp (from table)) = 47cp (from table) μμ((209.8F209.8F) = 47cp) = 47cp μμ((210.7F210.7F) = 46 cp) = 46 cp
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Calculate the viscosities ratios equals to Calculate the viscosities ratios equals to μμww/ / μμbb
At TAt TBB =80F and T =80F and TWW = 209.6F = 209.6FVVISIS=47/1000=0.047=47/1000=0.047
At TAt TBB =130F and T =130F and TWW = 209.8F = 209.8FVVISIS=47/270=0.174=47/270=0.174
At TAt TBB =80F and T =80F and TWW = 209.6F = 209.6FVVISIS=46/85=0.541=46/85=0.541
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STEP 7:STEP 7:NNNUNU = 0.73(N = 0.73(NRERE))0.650.65(N(NPRPR))0.33(0.33(μμww/ / μμbb))0.140.14
As As NNNUNU = h = hii D DTT/k/khhii(80F) =38.4 Btu/(F) (hr) (sq.ft)(80F) =38.4 Btu/(F) (hr) (sq.ft)hhii(130F) =42.2 Btu/(F) (hr) (sq.ft)(130F) =42.2 Btu/(F) (hr) (sq.ft)hhii(180F) = 46.7Btu/(F) (hr) (sq.ft)(180F) = 46.7Btu/(F) (hr) (sq.ft)
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STEP 8:STEP 8:1/Ui = 1/hi+ x/k +1/hs 1/Ui = 1/hi+ x/k +1/hs hi= as calculated in step 7hi= as calculated in step 7x= 1/8 in =0.0104 ftx= 1/8 in =0.0104 ftK= 9.4 Btu/(hr)(sq.ft)(F/ft) for the vessel K= 9.4 Btu/(hr)(sq.ft)(F/ft) for the vessel
wallwallhhss= 1000 Btu/(F) (hr) (sq.ft) = 1000 Btu/(F) (hr) (sq.ft)
UUii(Tb=80 F) =0.0281 Btu/(F) (hr) (sq.ft) (Tb=80 F) =0.0281 Btu/(F) (hr) (sq.ft) UUii(Tb=130 F) =38.7 Btu/(F) (hr) (sq.ft) (Tb=130 F) =38.7 Btu/(F) (hr) (sq.ft) UUii(Tb=180 F)= 42.5 Btu/(F) (hr) (sq.ft) (Tb=180 F)= 42.5 Btu/(F) (hr) (sq.ft)
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Ui at different time intervals
35
36
37
38
39
40
41
42
43
0 50 100 150 200
Tb(F)
Ui
Ui
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STEP 9:STEP 9:Time taken to heat the liq over each Time taken to heat the liq over each
temp increment is calculated by this temp increment is calculated by this formulaformula
TThrhr=(MC=(MCPP/U/UiiAAii) ln [T) ln [TSS – T – TII/T/TSS –T –Tff]]
Liquid mass= Liquid mass= ππ(D(Dtt22/4)(H/4)(Htt)()(ρρ))
= = ππ(36/4)(6)(60)(36/4)(6)(60) =10180 lb =10180 lb
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Time reqd to heat the nass from 80 to 100 F Time reqd to heat the nass from 80 to 100 F is calculated asis calculated as
t(80-100F) t(80-100F) = (10180)(0.6) ln (212-80)= (10180)(0.6) ln (212-80) (36.15)(113) (212-100)(36.15)(113) (212-100) =0.242 hr=0.242 hr t(100 -120F) = 0.283 hrt(100 -120F) = 0.283 hr t(120 -140F) = 0.340 hrt(120 -140F) = 0.340 hr t(140-160F) = 0.439 hrt(140-160F) = 0.439 hr t(160-180F) =0.630 hrt(160-180F) =0.630 hrTotal Time = 1.934 hrTotal Time = 1.934 hr
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Approximate method:Approximate method:TThrhr=(MC=(MCPP/U/UiiAAii) ln [T) ln [TSS – T – TII/T/TSS –T –Tff]]TThrhr=(10180*0.6/38.7*113) =(10180*0.6/38.7*113) *ln [212-80/212 -180]*ln [212-80/212 -180]TThrhr=1.981 hr=1.981 hr
Value differ by only 2.4%Value differ by only 2.4%