Liptak Distillation eBook

Distillation Control & optimization An Ebook by Béla Lipták

proloGue

G

iants o the automation automation industry are ew ew.. Béla

plants. Although volumes have been written on dis-

Lipták is one. From his beginnings in the

tillation control, most columns are not optimized. In-

Hungarian resistance movement to his vol-

strument and process engineers will nd a practical,

umes o work on automation and control, he has ha s proven

readable treatment o the subject that can be applied

himsel to be one o the great thinkers thin kers and authorities authorities in

quickly and eectively. e ectively.

the industr industry. y. In this ebook, Distillation Control & Op-

Like other publications rom ControlGlobal.com, ControlGlobal.com, the

timization, he provides a concise,

Distillation Control & Optimiza-

yet complete analysis o distilla-

tion ebook is eective without

tion control, showing “the po-

being laborious. It provides oSM

tential or savings through better

cus on the important aspects o

control and optimization.” optimi zation.”

the subject or the time-pressed

In a practical, intuitive w ay, ay, Lipták emphasizes reli-

engineer who is responsible or distillation optimiza-

able stable control strategies aimed at optimization o

tion. We are proud proud and honored honored to assist in bringing bringing

process perormance. perormance. He claims claims that these optimiza-

this important work to the automation community.

tion techniques can improve “productivity and protability by 25% 25%.” .” I believe him. Distillation is arguably

martin Berutti

the most complex unit operation in most processing

MYNAH Technologies

www.controlglobal.com

––

proloGue

G

iants o the automation automation industry are ew ew.. Béla

plants. Although volumes have been written on dis-

Lipták is one. From his beginnings in the

tillation control, most columns are not optimized. In-

Hungarian resistance movement to his vol-

strument and process engineers will nd a practical,

umes o work on automation and control, he has ha s proven

readable treatment o the subject that can be applied

himsel to be one o the great thinkers thin kers and authorities authorities in

quickly and eectively. e ectively.

the industr industry. y. In this ebook, Distillation Control & Op-

Like other publications rom ControlGlobal.com, ControlGlobal.com, the

timization, he provides a concise,

Distillation Control & Optimiza-

yet complete analysis o distilla-

tion ebook is eective without

tion control, showing “the po-

being laborious. It provides oSM

tential or savings through better

cus on the important aspects o

control and optimization.” optimi zation.”

the subject or the time-pressed

In a practical, intuitive w ay, ay, Lipták emphasizes reli-

engineer who is responsible or distillation optimiza-

able stable control strategies aimed at optimization o

tion. We are proud proud and honored honored to assist in bringing bringing

process perormance. perormance. He claims claims that these optimiza-

this important work to the automation community.

tion techniques can improve “productivity and protability by 25% 25%.” .” I believe him. Distillation is arguably

martin Berutti

the most complex unit operation in most processing

MYNAH Technologies


––

Distillation Control & optimization

D C d o – p 1

FeeD Co Controls                            22

Maximizing Feed Flow . . . . . . . . . . . . . . . . . . . . . . . . . 22

tHe proCess                              4

The Column . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

Feed eed Tem Tempe pera ratur turee and and Entha Enthalp lpyy Con Contr trol ol . . . . . . . . . . . 24 reFluX Co Controls                           24

Col Column Vari ariables and The Their Pairi airing ng . . . . . . . . . . . . . . . 7 Assigning Assig ning Variables, Relative Gain Calculations . . . . . . 7 Composition Control                       9

Indirect (Tempera (Temperature-Based) ture-Based) Composition Composition Control . . 9 Composition Me Measurement . . . . . . . . . . . . . . . . . . . . . . 10

D C d o – p 3 Controlli llinG tHe WHole Column             25 Constant separation                     27

Analyzer Selection Select ion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Maximum Re R ecovery . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 Analyzer Sampling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Com Composi positi tioon Cont Contro roll Using sing Anal Analyz yzer erss . . . . . . . . . . . . . 14 Smith Predictor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14

Com Compos positi ition Con Control trol o Two Prod Produ ucts cts . . . . . . . . . . . . . 27 Two Products With Interaction . . . . . . . . . . . . . . . . . . . 29

Triple Ca Cascade . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

Feed Com Compositio tion Com Compensation . . . . . . . . . . . . . . . . . 30

Selective Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

multiple proDuCt Di Distillat lation              31 31

Multivariable Control . . . . . . . . . . . . . . . . . . . . . . . . . . 31

D C d o – p 2

Model-Based Co C ontrol . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 Articial Art icial Neural Networks (ANN) . . . . . . . . . . . . . . . . . 34

pressure Control                         16

Cool Coolin ingg Wat Water er Cont Contro rol, l, Negl Neglig igib ible le Iner Inerts ts . . . . . . . . . . . 17

The To Total Mo Model . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Sub-Op b-Opti tim miza izatio tion o Un Unit Ope Operatio tions. . . . . . . . . . . . . . 36

Distillate With Inert s . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Operating Equations . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 Bypass Co Control Co Congurations . . . . . . . . . . . . . . . . . . . 18 Optimization: Mi Minimum Pressure . . . . . . . . . . . . . . . . 19 Vacuum Vacuum Systems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

total optimization                        39

Product Price Considerations . . . . . . . . . . . . . . . . . . . . 39

Reboilers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

Operating Constraint s . . . . . . . . . . . . . . . . . . . . . . . . . . 39

Vapor Recompression . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40


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p 1

D

uring the global transition rom the present oil-based economy to one based on clean and inexhaustible energy, the importance o distillation distill ation will increase. Ethanol will need to be distilled, dist illed, and new oil reneries will need to be built. It is hoped that the designers o these new reneries will benet rom this di scussion, which describes the state o the art in the control and optimization o distillation processes.

Distillation is a common, energy-intensive energy-intensive method o separation in the petroleum, chemical, ood, pulp and paper and pharmaceutical pharmaceutical industries. Globally, Globally, more than 80 million barrels o crude oil are rened daily. daily. In the t he U.S., 146 reneries operate, employing over 65,000 people and producing a total value that exceeds $151 billion. But no new renery has been built in the U.S. since 1976, 1976, and the t he technology technology in use today is not much dierent rom that used on the rst distillation columns in the 19th century. The thermal energy requirements o distillation are enormous. The thermodynamic eciency o distill ation processes is less than 10%. The amount o energy used or distillation is approximately 8% o the total energy used in the industrial industria l sector o the t he U.S. Reneries Reneries spend 50% to 60% o their operating costs (excluding excluding capital costs and depreciation) on energy, energy, while the t he chemical industry spends only 30% to 40%. This T his dierence di erence shows shows the saving potential o implementing implementing better bet ter control and optimization o the distillation process. My main reason or writing this ebook is to show how these increases in efciency and savings can be accomplished accomplished by the applicaapplication o state-o-the-art process controls.

I will rst describe the distillation process, its components components and dynamics. Next I will discuss the traditional PID-based control system congurations, which are still used in the majority o the operating reneries. I will conclud concludee with a review o st ate-o-the-art distill ation optimization strategies, including including multivariable, model-based and articial neural network-based control systems, where the process variables are used only as constraints, and the production rate and eciency are continuously optimized. I hope to show that advanced controls can cut the operating costs and internal energy consumption o reneries and other distillation processes by 25%. tHe proCess

Distillation is the most requently used separation process. It separates the components o a mix ture on the basis o their boiling points and on the dierence di erence in the compositions o the liquids and their vapors. The product purity o a distillation process is maintained by the manipulation o the material and energy balances. Diculties in maintaining that purity arise because o dead times, t imes, nonlinearities and variable interactions. interactions. Distillation can be perormed either as a batch or a continuous operation. The main dierence between the two is that t hat in continuous distillation, the eed concentration is relatively constant, while in batch, the concen concentratration o the light li ght components components drops and that o t he heavy components components rises as distillation distillat ion progresses. Another basic dierence di erence between distillation operations is in i n the handling o the heat removed by the condenser at the top o the column. The more common approac approach h is to waste wa ste that heat by rejecting it into t he cooling water. In this case, “pay heat” must be used at the bottom o the column in the reboiler. reboiler. Figure 1 (p. 5) illustrates this conguration and identies its it s main components. Because a large part o the t he total operating cost is in providing the heat required at the reboiler in some distillation systems, the t he heat content content o the t he bottom product is used to preheat the eed to t he column. www.controlglobal.com

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Distillation Control & optimization FiGure 1

V Condenser –Q Column

Accumulator

L Feed pump

D (y)

F (z)

Reflux pump

Preheater V

B

Reboiler +Q

B (x) Illustration o a tray-typ distillation towr, whr (without accumulation), th matrial balanc is F = D + B and D = V – L. Th mol r actions o t h light ky componn t in th bottoms, distillat an d d ar id ntid as x, y and z. For bin ary s paration, S = (y[1-x])/(x[1-y]).

The other option is to recycle the heat removed at the condenser by a heat pump (compressor). In this conguration, as the vapors rom the column (V) are condensed, the heat rom the condenser is used to vaporize a working fuid. These vapors are at the low pressure o the suction side o the compressor (heat pump). When the working fuid vapors are compressed, and these high-pressure (and temperature) vapors in the reboiler contact the bottoms liquid rom the column, they condense, and their heat o condensation serves to vaporize the liquid rom the column bottoms (Figure 13, let, p. 21). While vapor recompression is energy-e cient, it is not used very requently. th C

The main distillation equipment is the column, tower or ractionator . It has two purposes: First, it separates a eed into a vapor portion that ascends the column and a liquid portion that descends; second, it achieves intimate mixing between the two counter-current fowing phases. The purpose o the mixing is to get an eective transer o the more volatile components into the ascending vapor and a corresponding transer o the less volatile components into the descending liquid The separation o phases is accomplished by the dierences in vapor pressures, with the lighter vapor rising t o the top o the column and the heavier liquid fowing to the bottom. The portion o the column above the eed is called the rectiying section and below the eed, the stripping section. The intimate mixing is obtained by either lling the column with lumps o an inert material ( packing) or by the use a number o horizontal plates, or trays, which cause the ascending vapor to bubble through the descending liquid (Figure 2, let, p. 6). www.controlglobal.com

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X(t) Y 40

Y 10

Y 4

Y 2

Y 1

L

L

L Y 1 = 1 Lag Y 2 = 2 Lags Y 4 = 4 Lags Y 1 0 = 10 Lags Y 4 0 = 40 Lags

Sum of the time constants are equal Time

Lt: Th contact btwn liquid and vapor is mad intimat as th vapors ascnd through th liquids hld on ach tray as th liquid dscnds. Th dynamics o a multipl-tray column can b approximatd as a scond-ordr lag, plus dad tim. Right: Th rspons s o th distillat composit ion (y) o 1st-, 2nd-, 4th-, 10th- and 40th-ordr proc sss ar shown wh n a unit stp chang in bottoms composition (x) occurs. A 40-tray column is a 40th-ordr procss.

Generally trays work better in applications requiring high fow, such as those encountered in high pressure distillation columns—depropanizers, debutanizers, xylene purication columns and t he like. Packing works best at lower fow parameters because the low pressure drop o structured packing makes it very attractive or use in vacuum columns or ethylbenzene recycle columns o styrene plants. The infuence o plate eciency in the operation o the distillation tower becomes important in the control o the overhead composition. Because plate eciencies increase with increased vapor velocities, the infuence o the refux-to-eed ratio on overhead composition becomes a nonlinear relationship. Column dynamics are a unction o the number o trays, because the liquid on each tray must overfow its weir and work its way down the column; thereore, a change in composition will not be seen at the bottom o t he tower until some time has passed. These lags are cumulative as the liquid passes each tray on its way down the column. Thus, a 30-tray column could be approximated by 30 rst-order exponential lags in a series o approximately the same time constant. The eect o increasing the number o lags in series is to increase the apparent dead time and increase the response-curve slope. Thus, the liquid trac within the distillation process is oten approximated by a second-order lag, plus dead time (Figure 2, right). www.controlglobal.com

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C Vb d th pg

Controlled variables include product compositions, column temperatures and pressure, and tower and accumulator levels. Manipulated variables include refux, coolant, heating medium and product fows. Load and disturbance variables include eed-fow rate, eed composition, steam-header pressure, eed enthalpy, environmental conditions (e.g., rain, barometric pressure and ambient temperature) and coolant temperature. The general guidelines or pairing manipulated variables with controlled variables are as ollows: • Manipulate the stream that has the greatest infuence on the controlled variable. • Manipulate the smaller i two streams have the same eect on the controlled variable. • Manipulate the stream that is more nearly linear with the controlled variable. • Manipulate the stream that is least sensitive to ambient conditions. • Manipulate the stream least likely to cause interaction. In a binary distillation process, the number o independent variables is eleven, and the number o dening equations is two. Thereore, the number o degrees o reedom is nine. Consequently, the maximum theoretical number o automatic controllers that can be used on a binary distillation process is nine, but usually only ve are controlled. These variables are the compositions o the bottom and top products ( x and y), the levels in the column base and accumulator, and the column pressure. The manipulated variables that can be assigned to control these are the distillate ( D), bottoms (B) and refux (L) fows, the vapor boil-up ( V set by heat input QB), heat removal ( QT ) and the ratios o L/D or V/B. These ve single loops can theoretically be congured in 120 dierent combinations, and selecting the right one is a prerequisite to stability and eciency. Column pressure almost always is controlled by heat removal ( QT ). This loop closes the heat balance around the column, while the levels are controlled to close its material balance. Thereore, the key task is the assignment o the manipulated variables to the composition controllers. No matter how we make that selection, these two loops will interact. A change in one will upset the other because whenever the openings o their control valves change, the material and heat balance o the column will also change. Thereore, the most important decision in designing the distillation controls is to assign the least-interacting manipulated variables to the composition control loops. The tool used in making that selection is the relative gain (RG) calculation. agg Vb, rv G Cc

The RGs o the t wo composition loops are calculated as the ratio o t heir open-loop gains when the other loop is open (in manual,) divided by their open-loop gains when the other loop is closed (in automatic). The open-loop gain can be measured by manually changing t he valve opening by, say, 1% and reading the resulting percentage change in the controlled variable when the new steady st ate is reached. The higher the ratio o controlled-to-manipulated variable response, the higher will be the open-loop gain and, thereore, when the loop is closed (placed in automatic), the lower the controller gain (wider proportional band) has to be to obtain stable control. Naturally, the ideal RG is 1.0. RG = 1 indicates that the loop gain is unaected (the tuning o the loop does not need to be changed) when the other loop is switched rom manual to automatic or back. Consequently, our goal o selecting the combination o loops with the least interaction is to nd pairings with RG values near unity (not much above or below RG = 1). For the various equations to be used in making RG calculations, see Chapter 2.25, Vol. 2, The Instrument Engineer’s Handbook, 4th edition. I RG is zero, that indicates that the manipulated variable has no direct infuence, and the loop can only control through interaction with the other loop. Consequently, the process is controllable only when the www.controlglobal.com

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other loop is closed (in automatic). Similarly, a very high RG value (say, 100), indicates that the process is controllable only i the other loop is open (in manual). Negative RG values will reverse the control ler action and should never be considered. I the RG is bet ween 0 and 1, the eedback rom the interaction i s negative and when RG > 1, the eedback rom the interaction is positive. Loop congurations with RG values that are < 0.5 or > 10 should be rejected, while RG values in the range o 0.5 to 10 are controllable. Naturally, the urther the RG is rom 1.0, the worse the interaction. About t he same amount o interaction is indicated by an RG value o 0.5 and an RG value o 10. Figure 3 illustrates a possible result o calculating t he RG values. Here it was concluded that xing the production rate (heat input to the column QB) and controlling only the distillate composition ( y), while allowing the bottoms composition ( x) to foat, will give the most stable and ecient operation. FiGure 3

Qt

LC

l a

PC

FC

(D, y)

L

FC

TC

(F, z)

V

FC

l b

LC

QB

FC

(B, x)

In this xampl, th v manipulatd variabls ar so assignd to th v controlld variabls that th hat input at th r boilr (Q B) and th distillat composition (y) ar xd and, thr or, th bottoms fow (B) and c omposition (x) ar allowd to chang with th variations in d fow (F) or composition (z). www.controlglobal.com

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Composition Control Conceptually, product quality is determined by the heat balance o the column. The heat removal determines the internal refux fow rate, while the heat addition determines the internal vapor rate. These internal vapor and liquid fow rates determine the circulation rate, which in turn determines the degree o separation bet ween two key components. The rst task in conguring the control system or a distillation column is to congure the primary composition control loops. This conguration must consider the interaction between the proposed control loops, the column’s operating objectives and the most likely disturbance variables. The measurements o the composition control loops can either be direct or inerred. Figure 4 provides some guidance on how to select t he manipulated variables or controlling the compositions (and levels) o distillation columns. FiGure 4

Dyc r d svy l  h pg  D C Vb (I both compositions ar important, thy should not both b controlld by matrial balanc [B, D]) Manipulatd Variabls Controlld Variabls

Composition o Ovrhad Product (y)

Distillat Flow (D)

Vaporizatio n Rat (V) or Hat Input at Rboilr (Q)

Rfux Flow Rat (L)

Nots 1 and 2

Not 2

Nots 1 and 2

OK i trays ≤20

Not good with urnac. OK i V/B ≥ 3

OK i L/D ≥ 0.5

OK i L/D ≥ 6 Not 3

Composition o Bottoms Product (x) Accumula tor Lvl

Bottoms Product Flow (B)

Not 3 OK i L/D ≤ 6

Bottoms Lvl

OK i V/B ≤ 3

Not good i urnac is usd. OK i diamtr at bottom ≤ 20 t.

Nots: 1. Controls th concntration (x or y) which has th shortr rsidnc tim by throttling vapor fow (v). 2. Mor pur product should control sparation (nrgy). 3. Lss pur product should control matrial balanc. 4. Whn controlling both x and y, th only choics or possibl pairings ar a. Control y by D and x by V, b. Control y by D and x by L, c. Control y by L and x by V, d. Control y by B and x by L. O ths choics, d is not rcommndd bcaus a y/B combination is not rsponsiv dynamically.

idc (t-Bd) C C

I the eed composition and the column pressure are constant, temperature can be used as an indirect measure o composition. I the column pressure is not constant, the temperature measurement must be pressure-compensated. When the bottom product composition is controlled, the temperature sensor is located in the lower hal o the column, and when overhead composition is controlled, in the upper hal. The temperature sensor should be located on a tray t hat strongly refects changes in composition. This means a 1% change in the manipulated variable (refux or steam fows in Figure 5, p. 10) should result in a temperature change o at least 0.1 ºC to 0.5 °C, and that this change should be symmetrical, meaning that a 1% drop or rise in these fows should result in approximately the same size o drop or rise in the temperature on the control tray. When two compounds o relatively close vapor pressures are to be separated (or example normal butane rom isobutene), temperature measurement is not sensitive enough to measure composition. In such cases, two temperatures or a temperature dierence (say, between Trays 5 and 15) can be used instead o a single sensor. This conguration can also be used to eliminate the eects o column pressure variations. www.controlglobal.com

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V Water

Condenser

(-Q) PRC

PT TRC

Set TT

Accumulator

FRC

LT

LRC

Set

FT FRC

L

FT

D(y)

TRC

TT

Set FRC

Reboiler

FT

(+Q)

Steam LT

LIC

B(x)

Top: Distillat composition can b controll d by a c ascad tmpratur mastr on th uppr par t o th column, which ma nipulats th rfux fow L. Bottom: Similarly, th bottoms composition can b controlld by a cascad tmpratur mastr locatd on th lowr hal o th column, throttling th rboilr hat input.

C m

The direct measurement o composition is more expensive, but also more accurate and versatile than is indirect temperature measurement. Intermittent analyzers, such as chromatographs (with cycle times o a ew minutes), are oten provided with dead time compensation or closed-loop control. The analyzer update time must always be less than the response time o the process. For improved accuracy, one usually measures the impurity concentration in the controlled stream. This way the upsets caused by eed composition changes, tower pressure or eciency variations can be more accurately corrected. In the case o ractionator trains, t he bottom or distillate analyzer on one column can also be the eed analyzer on the next one. In such processes, one can control either the concentration o a single component or the ratio o two components (Figure 6, let, p. 11). As will be shown later, such decisions can be based on protability and market considerations. www.controlglobal.com

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In order or the composition to be close to the terminal composition, the point at which the measurement is made must also be near the column terminals. This will also minimize the transportation lag (dead time). In some applications though, the sampling point is moved closer to the column eed because that provides earlier recognition o eed composition changes or because the key control component is present at a higher concentration. Figure 6, right, describes some o the actors that should be considered in sample point selection. The samples should always be ltered, dried and cooled, and their dead t imes (transportation lags) must not exceed 30 seconds. Transportation lags can be reduced by the installation o high-fow bypasses. ay sc

Most o the 66 types o analyzers that are discussed in Chapter 8, Vol. 1, The Instrument Engineer’s Handbook, 4th edition, can also be used to control the dist illation process. On the LNG train (Figure 6, let), in the depropanizer (where isobutane is to be measured in the presence o ethane, propane and normal butane) and in the deisobutanizer (where isobutane is to be measured in the presence o normal butane and isopentane), an inrared analyzer is recommended. In the debutanizer, where the combined isopentane plus normal pentane concenFiGure 6

AX C3 Ethane product

NGL

r e z i n a h t e e D

AX C2/C3

Ok (fast but not repeatable) AX NC4

AX IC4

r e z i n a p o r p e D

AX C3/IC4

AX C5+

r e z i n a h t u b e D

NG

Isobutane product

Propane product

Ok (slow)

Distillate product NG (D)

r e z i n a h t u b o s i e D

Feed (F)

N-butane product

Ok (fast)

AX IC4

Straight run gasoline

Ok (slow & low pressure)

AX NC4

Ok (slow)

Bottoms product (B)

Lt: Rcommndd analyzr locations on ractionator trains. Right: Sampling point considrations on individual columns.

trations are measured in the presence o isobutane and normal butane to control the butane-pentane separation, gas chromatography is recommended. Some physical properties analyzers, such as boiling-point analyzers, are reliable enough to be used or online control (see Chapter 8.48, Vol. 1, The Instrument Engineer’s Handbook, 4th edition). Cut points between overhead products and side-cuts can be controlled on the basis o temperature, but doing so results in the downgrading o the more valuable product to the stream o lesser value. This downgrading can be minimized through the use o online boiling point analyzers. Justication o a boiling point analyzer depends upon the value o the products and the cost o analyzer maintenance. www.controlglobal.com

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Viscosity can also be measured continuously to give aster control in vacuum distillation. The use o a viscosity analyzer minimizes downgrading during major upsets and large eed composition changes. With such an arrangement, low-viscosity vacuum bottoms can be detected quickly and diverted to recoverable eed or protable reprocessing. Many other analytical instruments are being moved out o the laboratory and into the processing area. Mobile units containing several dierent kinds o analyzers can be used to learn the best place to locate the on-stream analyzers. In cases in which permanent analyzers cannot be justied, the mobile unit is connected to the process long enough to nd the best operating conditions. Then the mobile unit can be moved elsewhere. Recently articial neural networks (ANN) have also been used as indirect analyzers. In Fig ure 7, the product specications are based on the Reid vapor pressure in the bottoms product and on the 95% boiling point o the distillate. Using ANN sotware eliminates the problems o dead time, cost and availability limitations o direct analyzers. ANN uses a nonlinear neural network model, which iners the analytical readings on the basis o other measurements. I historical data exists, the model can be developed based on collected laboratory or analyzer results, as commonly recorded on log sheets. Figure 7 illustrates the case where the Reid vapor pressure o the bottoms product and the boiling point o the distillate are predicted by an ANN model. This particular model has nine measurements (input nodes), our hidden nodes and two output nodes with bias. FiGure 7

RVP IN

DISTILLATE

BOTTOMS

95% BP

OUTPUT LAYER (2 NODES)

HIDDEN LAYER (4 NODES)

INPUT LAYER

BIAS

(9 NODES)

BOTTOMS

FEED

BOTTOMS

FEED

FLOW

FLOW

TEMP DISTILLATE

STEAM

FLOW

FLOW

PRESSURE

TEMP TOP TEMP

REFLUX TEMP

ANN modl-bas d sot war c an provid indirct analy tical r ading pr dictions, ovrcoming d ad tim, av ailability and cost limitations o onlin analyzrs.


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ay sg

The sample system must condition the sample to remove traces o oreign materials t hrough ltering, maintain pressure and temperature, and maintain or change phase or introduction into the analyzer. The description o the wide variety o samplers, probes, lters and other sampling system components is beyond the scope o this work and is covered in detail in Chapter 8.2, Vol. 1, The Instrument Engineer’s Handbook, 4th edition. The system must transport the sample rom the sample point to the analyzer with a minimum o transport lag (preerably less than 30 seconds and denitely not greater than one minute). Transportation times are minimized by using high-fow-rate bypass streams taken rom the process sample point. With a circulation sample pump, care must be taken to prevent cavitation by locating the pump close to the sample take-o. Single-line transport is the most direct approach and is used when the sample line volume is small in relation to the analyzer sample consumption, so that the transport time lag is reasonably short. (See the tabulation at the bottom o Figure 8, p. 14). Ater selecting the appropriate sample transport method, a calculation o the sample time lag should be made, based on the ollowing: • Available dierential pressures, • Total length o the ast loop rom the sample take-o point to the analyzer location and back to the sample return point, • Line sizes, • Viscosity o the sample. Sample disposal is a critical consideration, both rom an economic and an ecological perspective. One goal is to prevent the emission o most hydrocarbons into the air. When there is an economic justication or saving the sample, as when dealing with liquids at the boiling point and viscometer analyzers, a sample collection and return system must be urnished to collect the sample at atmospheric pressures and pump it back at high pressure into the process. For gases with no sample return point, the sample can be pressurized back in to the process, or as is most requently done, vented in to the fare system. For chromatographs, liquid sample points are generally preerred (Figure 8) because o condensation at the sample probe and in the sample lines when hydrocarbons with high boiling points are present in the sample. When the sample lines are long, some separation between components can also occur. A satisactory point or measuring bottoms product composition is at the point o highest pressure immediately ater the product pump. However, i liquid holdup in the reboiler and kettle is large, a long lag is introduced, so an alternative sample point, such as a bottoms tray or seal pan may be used. A satisactory sample-point location or measuring the distillate is the outlet liquid o the overhead vapor condenser. Sampling the overhead accumulator liquid ater the refux or distillate pump should be avoided because o the tremendous process lag it introduces. Sampling the overhead vapor reduces the process lag o sampling ater the condenser i a repeatable, representative sample can be obtained. Figure 9, Part B, (p. 15) shows the same conguration as Figure 9, Part A, except that the analyzer controller is equipped with a rst-order Smith predictor (discussed on page 15) which provides dead time compensation. www.controlglobal.com

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Analyzer Sample Out

Pressure Temperature gauge gauge

Cooling Water in out

In

PI Control valve

TI

Flow indicator

FI

Self cleaning filter Sample cooler

Pressure regulator

Shut-off valves FI

Calibration sample

Shut-off valves

Coalescer

Lab sample take off

Pressure relief valve

Pressure gauge

Flow indicator FI with needle valve

Flow indicator

Flow indicator with needle valve

FI

PI Check valve

Check valve

Shut-off valve To drain

Top: Rnry chr omatograph liquid sampling systm a nd its componnt s. Bottom: Tubing or pip volums and dimn sions.

D d V  tbg d p ud  s sy Typ

316 stainlss stl tubing

Schdul 40 pip

Nominal Volum peR DIAmtr, in.

Innr Diamtr, in.

/8

Intrnal Ara in2

cc

.0787

.0048

.9571

¼

0.1850

0.0268

5.3035

/8

0.0253

0.0684

13.4417

½

0.4055

0.1290

25.2984

¼

0.3642

0.1040

20.4521

/8

0.4921

0.1891

37.4904

½

0.6220

0.3038

59.7408

¾

0.8268

0.5863

106.6800

C C ug ay

Analyzer controllers in a eedback conguration can be considered only when the dead time caused by analysis update is less than the response time o the process. Naturally, direct control o the composition o the product by an analyzer gives more accurate results than indirect control by temperature. The composition controller provides a eedback correction in response to eed composition changes, pressure variations or changes in tower eciencies. In Part A o Figure 9, the analyzer controller (ARC) uses the chromatographic measurement to manipulate the refux fow by adjusting the set point to the refux fow controller (FRC). A liquid sample rom the condenser run-down line is obtained by a sample probe, and a sample system is used to condition and vaporize the liquid sample to provide a representative vapor sample to the chromatograph. sh pdc

Oten the analy zer is slow and introduces a signi icant delay time that degrades the controllability o t he process. In that ca se, some type o dead time compensation is use d. (Section 2.30, Vol. 2, The Instrument Engineer’s Handbook, 4th edition.) A Smith-predictor compensator can serve to model the process to www.controlglobal.com

– 1 –


SP

SP FT

FT

FRC

∑ ARC ARC

PRC

PT

TT

FT

Accumulator

PT

D

L

AT

X

PRC

SP FRC

AT

+ ∆ + AY AY + -

FRC

TT

AY

1

2 Lag

SP FRC

A

AY

FT

AY 3 Dead time Accumulator D

L

B SP FT

ARC

SP

PRC

r e p p i r t s r e b r o s b A

FRC

AT

TRC

PT

TT

D

SP

FY

<

TRC

SP FRC

FT

Accumulator

FRC

FT

L

D

Reboilier ARC

C

Lean oil to absorber

Part A: Ovrhad composition controls by cascading rfux fow as th slav controllr (FRC). Part B: Th Smith prdictor, which is th sam as Par t A, but with dad tim compnsation addd. Part C: Ovrhad composition control by tripl cascad o ARC to TRC to FRC. Par t D: Absorbr bottoms composition control (ARC) cascadd to rboilr hat input (FRC) with tmpratur ovrrid (TRC).

predict what the analyzer measurement should be between analysis updates. When the actual measurement is completed, the model’s prediction is compared to the actual measurement, and the input to the controller is biased by the dierence. Controllability o the process is degraded by the dead time between measurement updates. (Dead time compensation in detail is discussed in Chapter Section 2.30, Vol. 2, The Instrument Engineers Handbook, 4th edition). As shown in Part B o Figure 9, the Smith predictor compensator provides a process model in terms o its time constant and dead time, and thereby predicts what the analyzer measurement should be between analysis updates. When an actual analysis is completed, the model’s prediction is compared to the actual measurement, and the input to the controller is biased by the di erence. In Figure 9, Part B, the multiplier ( AY1), rst-order lag ( AY2) and dead time ( AY3) provide the required inputs to the calculation o the predicted analysis. This predicted response is subtracted rom the act ual measurement ( AY±) to give a di erential o the actual process rom its own model. This delta is added to the model ( AY∑) without dead time to provide a modied pseudo-measurement to the analyzer controller. Thus, the analyzer measurement, which has a signicant dead time due to sampling and cycle times, is provided with a trim to obtain the predicted measurement o the model. www.controlglobal.com

– 1 –


t Ccd

The purpose o all cascade systems is to provide slaves that will correct or dist urbances beore they can upset the primary or master controller. Part C in Figure 9 illustrates a triple-cascade loop, where a temperature controller is the slave o an analyzer controller, while the refux fow is cascaded to temperature. This conguration is used when maintaining a stable temperature on a particular t ray, while the tower operates at a constant and controllable pressure is desired. Since temperature is an indicator o composition at constant pressure, the analyzer controller serves only to correct or variations in eed composition. Cascade loops will work only i the slave is aster than the master, which adjusts its set point. Thereore, in the case illustrated in Part C, the time constants o the fow controller (FRC) must be much smaller than those o the TRC and similarly, the TRC must be aster than the A RC. Another important consideration in all cascade systems is that t he integral mode in the master will cause the output to saturate when that output is blocked rom reaching and modulating the set point o the slave (when the slave is switched to local set point). This is called “reset windup,” and it is prevented by providing the integral mode o the master with an input (an “external reset”) that is never blocked. The external reset o the master is always the measurement o the slave (temperature or the ARC, fow or the TRC, in Part C). These signals are not shown in Part C scv C

Part D o Figure 9 illustrates a limit control conguration where the analyzer controller is overruled when the temperature reaches its high limit. T he temperature controller is a constraint controller preventing the temperature rom exceeding a limit at the bottoms o an absorber stripper. The reason or this limit is energy conservation, because no additional stripping o the light component can be accomplished once the boiling point o the impurity is exceeded. Thereore, even though an analyzer controller may call or more heat, this heat would only increase the bottoms temperature without removing the impurity, thereby wasting heat. Selective control congurations also require external eedback to protect them rom reset windup. In Part D, we have a combination o selective and cascade systems as the master o the FRC is selected to be either the TRC or the ARC. In such a conguration, the external reset (ER) signal (not shown in the gure) is taken rom the measurement o the slave controller (FRC).

p 2 pressure Control n controlling the pressure o a column, the key pieces o equipment are the condenser and the accumulator. First the overhead vapors enter the condenser (partial or total), and next the liquid condensate is collected in an accumulator vessel. Some o the accumulated condensate is returned to the column as refux, while the remainder is withdrawn as overhead product (distillate). I the condensation is incomplete, the condenser is called a “partial” condenser, and the overhead product is withdrawn in both vapor and liquid phases. Total condensers are usually designed or accumulator pressures up to 215 psia (1.48 MPa) at an operating temperature o 120 ˚F (49 ˚C). A partial condenser is usually used between 215 psia and 365 psia (1.48 to 2.52 MPa), and rerigerant coolant, such as propane, is used i the operating pressure is greater than 365 psia (2.52 MPa). The condenser pressure drop is usually about 5 psia (34.4 KPa). Most distillation columns are operated under constant pressure, because at constant pressure, temperature measurement is an indirect indication o composition, but foating the operating pressure can have advantages in many applications. When the column pressure is allowed to foat, t he composition must be measured by analyzers or by pressure-compensated thermometers. The primary advantage o foating-pressure control is t hat one can operate at minimum pressure, and this reduces the required heat input needed at the reboiler. Other advantages o operating at lower temperatures include increased reboiler capacity and reduced reboiler ouling.

I


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In the ollowing paragraphs, foating and constant pressure control strategies will be described or operations when (1) liquid distillate is withdrawn in the presence o non-condensables; (2) vapor distillate is withdrawn in the presence o non-condensables; and (3) liquid distillate is withdrawn when the amount o non-condensables is negligible. Cg W C, nggb i

In distillation processes where the distillate is in the liquid phase and the quantity o inerts is negligible, the column pressure is usually controlled by modulating the rate o condensation in the condenser. In the control system shown or Column A in Figure 10 (p. 18), the column pressure is controlled by throttling the cooling water fow through the condenser. This control scheme is recommended only when the cooling water is treated, because condenser tube ouling due to high temperature rise across the tubes can occur. The advantage o this conguration is simplicity and low maintenance cost, because the control valve is on t he water side and gives acceptable control perormance, provided the condenser is the bundle type, and t he cooling water is fowing through the tubes at a rate over 4.5 eet per second (1.35 m/s), or the water has residence time o less than 45 seconds. With such short residence time, the pressure controller requires only a nar row proportional mode. As the residence time increases, the controller will require wider and wider throttling ranges and will also need the addition o an integral mode to compensate or the load changes. Once the proportional band is wide, the control quality will no longer be satisactory or precision distillation applications, because the recovery time rom upsets will be long, and because proper tuning o the integral mode is prevented, due to the dead time varying with load. Thereore, one should not use this control system when the process time lag is large, such as in a case where a condenser box with submerged tube sections is used, because o the large volume o water in the box. I the amount o inerts is nearly zero, and one would like to have a more responsive control system, one can relocate the control valve rom the water to the condensate liquid line on Column A in Figure 10. In such a conguration, when the column pressure is dropping, the pressure recorder controller (PRC) reduces the opening o this valve, which causes the condensate level to build up, and the tube surace exposed to the condensing vapors is reduced due to the fooding o the heat transer tubes. This reduces the rate o condensation and increases the column pressure. I it is expected that over time the inerts will accumulate and blanket the condenser, a vent valve should be added to the condenser. D wh i

The problem o pressure control can be complicated by the presence o large quantities o inert gases, which must be removed, because otherwise they will blanket the condensing surace and cause the loss o pressure control. In renery applications, the non-condensables are oten sent to the uel gas system or to fare. In other cases, a xed fow o inerts and vapors is purged to a lower pressure absorption tower or to a vent condenser, where the condensable vapors are recovered. When the amount o inerts is variable, the purge stream has to be modulated. In the control system shown or Column B in Figure 10, as the inerts build up in the condenser, the pressure controller will rst open up the control valve (PCV-1), which lowers the fooding level in the condenser and, by increasing the heat transer surace area, also increases the rate o condensation. When PCV-1 is nearly ully open (say 95%), the valve position controller (VPC-2) is activated. Its set point is 95%, so when PCV-1 has opened to 95%, it starts purging the inerts by opening control valve (VPCV-2). The control system shown or Column C in Figure 10 is used when the distillate is in the vapor phase and inerts are present. As the overhead product is removed under pressure control, the system pressure will quickly respond to changes in the distillate vapor fow. Here, the level o the overhead receiver regulates the condensate generated by throttling the cooling water supply. This way it will condense only enough material to provide the column with refux. This control system will give acceptable perormance only i the condenser residence time on the coolant side is short. I this is not the case, the cooling water fow should be held constant, and the control system shown or Column www.controlglobal.com

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o re-vaporizing the condensate, part o the overhead vapor stream is never condensed, but is sent to a vapor bypass valve around the condenser. This allows the condensate fow to stay constant, while varying the rate o condensation by changing the degree o fooding o the tubes. Column F in Figure 10 illustrates the controls when, in the case o liquid distillates with neglig ible inerts, the condenser needs to be mounted below the accumulator or ease o maintenance or to save on the steel supports. In this conguration, when the bypass valve is open, the condenser is fooded. When the column pressure drops, the PRC increases the opening o the bypass valve, which increases the pressure in t he accumulator and pushes some o the condensate back into the condenser to reduce its rate o condensation. I the column pressure rises, the opposite occurs, and the rate o condensation increases. It is usual practice to elevate the bottom o the accumulator 10 t to 15 t (3 m to 4.5 m) above the suction o the pump in order to provide the required positive suction head. Under normal operating conditions, the subcooling that the condensate received in the condenser is su cient to reduce the vapor pressure in the receiver. The dierence in pressure permits the condensate to fow up the 10 t to 15 t o pipe between the condenser and the accumulator. When the condenser is mounted above the accumulator and no inerts are present, two bypass valves can be used, as shown or Column G in Figure 10. The column pressure is maintained by PRC-1, which is throttling the fow o vapor through the condenser, while PRC-2 is maintaining the accumulator pressure by throttling t he bypass. This conguration provides aster pressure regulation or the column. In most applications, some inerts are also present, and in such cases the controls shown or Column H in Figure 10 are applicable. Here, the column pressure controller is throttling the hot vapor bypass, and the accumulator pressure controller is throttling the vent valve o the inerts. The accumulator PRC is set at about 5 psig below the tower pressure.

o: m p

Operating the column at the minimum possible pressure minimizes the energy cost o separation within the constraints o the system. Lowering this pressure increases the relative volatility o distillation components, and thereby increases the capacity o the reboiler by reducing the operating temperature, which also results in reduced ouling. Reducing pressure also aects other parameters, such as tray eiciencies and latent heats o vaporization. Yet composition control must take precedence over pressure optimization, and thereore the pressure optimization loop response must be much slower than that o the composition control loop. The eects o pressure changes also must be considered on the upstream and downstream units. For example, i the pressure o an upstream tower provides the driving orce to move product to a downstream tower, pressure minimization may not be practical. Fractionators using vapor recompression, such as a propylene splitter (Figure 13, p. 21) with a heat pump, may actually benet rom increasing the pressure rather than reducing it. Minimum pressure operation can be achieved by adjusting the set point o the pressure controller so as to keep the condenser ully loaded at all times. In order to prevent upsets caused by rapid set point changes, the valve position control (VPC) scheme shown or Column A in Figure 11 (p. 20) can be used to minimize the set point o the pressure controller, and thereby keep the condenser control valve in nearly the ully open position. The VPC should be an integral-only controller, with an integral time setting approximately 10 times that o the overhead composition controller. In addition, bumpless transer rom VPC to direct PIC control should be guaranteed by providing external reset, and the set point adjustment capability o the VPC should be limited i required by the process. The controls or Column B in Figure 11 serve to minimize the operating pressure o a partial condensing system with a vapor distillate product. Here the level controller (on the rerigerant side) serves to ully load the condenser in the long term, while the pressure controller corrects the short-term upsets. www.controlglobal.com

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Distillation Control & optimization FiGur e 11 Refrigerant vapor Condenser valve

Water

Condenser valve

LC Keeps condenser flooded in the long run

Refrigerant V

PI

PT

PIC

SP

I

VPC

Set at 90%

External feedback

A

Remote set PT

B

I VPC=10 ( IPIC )

PIC

D

L

V

PIC

PT

Remote set

F(x)

Steam

Air

Water PRC

Bias Vapor

PIC

PT

(D)

C

Condensate temperature sets PIC to control vapor composition

LT

TT

LIC

D D

D

Optimization and vacuum control stratgis. A: Minimizing (foating) prssur by maximizing coolant valv opning; B: Floating prssur control o part ial condnsr by maximizing condnsr lvl; C: Floating prssur control whn th distillat is both vapor and liquid; D: Vacuum controlld by air bld-in.

An additional control loop is required to control the composition o the vapor product (Column C, Figure 11) i the column pressure is foated and both liquid and vapor distillates are produced. In this control system, the column pressure is controlled by throttling the fow o the vapor distillate, while the set point o this PIC is adjusted i changes occur in t he accumulator (condenser outlet) temperature, which is characterized to represent the desired composition. I changes are to be made in the product composition, the bias is adjusted. Vc sy

To separate some liquid mixtures, t he temperature required to vaporize the eed would need to be so high that decomposition would result. These columns are operated under vacuum and steam jet ejectors can be used, singly or in stages, to generate the required vacuum. Ejectors have no moving parts and require litt le maintenance, but are designed to operate at a xed capacity and steam condition. Increasing the steam pressure above the design level will not increase and sometimes will decrease the capacity o the ejector because o choking. Reducing the steam pressure causes unst able operation. For the above reasons, the steam pressure is controlled at a constant value (PIC) in the conguration or Column D, Figure 11. In order to reduce the time lag, instead o the column pressure, it is the accumulator pressure that is controlled by the PRC, which modulates the amount o air or inert gas that is bled into the system. At low loads this results in a substantial waste o steam. Thereore, operating costs can be lowered by installing t wo ejectors and by automatically switching between the larger one and a smaller one to match the load. rb

As shown in Figure 12 (p. 21), reboilers can be internal or external, and operated by either natural or orced circulation. The kettle reboiler is the most common design or external orced-circulation applications. Thermosyphon reboilers (vertical or horizontal) operate by natural circulation, which is induced by the hydrostatic pressure imbalance between the liquid inside the tower and the two-phase mi xture in the reboiler tubes. www.controlglobal.com

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A newer development is the use o sel-cleaning, shell-and-tube heat exchangers or applications where heat exchange suraces are prone to ouling. Common heat sources include hot oil, steam, uel gas (red reboilers) and the condensation o compressed vapors in vapor recompression systems. FiGure 12

V

V

Q Q

V

Q Q

L B

B

B Internal

B Horizontal thermosyphon

Vertical thermosyphon

External kettle

Rboilr dsign variations ar distinguishd by th typ o circulation—natural and orcd (pumpd)—and by th point rom which thy tak t hir liquid. Most r boilrs tak thir inlt r om th column bottoms, whil horizontal thrmosyphon rboilrs tak it rom th bottom trays.

V rc

Vapor recompression is another means o improving energy eciency. As shown in Figure 13, the overhead vapor rom the distillation column is compressed to a pressure at which the condensation temperature is greater than the boiling point o the process liquid at the tower bottoms. T his way the heat o condensation o the column overhead is reused as the heat or reboiling the bottoms. This scheme is known as vapor recompression. It is oten used when the boiling points o the top and bottom products are similar. Examples o such processes are the cryogenic demethanization processes, where the column pressure is controlled by throttling the speed o the recompression compressors or the propylene ractionation process. As shown on the right o Figure 13, the propylene column pressure is controlled by throttling the bypass valve around the vapor recompression heat pump. FiGure 13

L

PT PR C

Heat pump

D M F

Compr.

Work

r e w o t

F

CW

e n e l y p o r P

TR C

SP Accumulator

FR C FT

Reboiler B

Recovered heat

Propylene – (C3 )

D

Propane (C3)

Lt: Th vapor rcomprssion systm uss rcovrd hat. Right: Th prssur o such a distillation procss can b controlld by modulating th spd o th comprssor or by throttling th bypass around it.


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FCCU main ractionators and crude towers also make use o compressors to “draw” vapors rom their essentially atmospheric towers and maintain the column pressure by manipulating the steam fow to the turbine, which sets the speed o the compressor.

FeeD Controls One o the best means o stabilizing the operation o a distillation column is to hold both the eed fow and temperature constant. Feed composition is seldom subject to adjustment. Having constant eed conditions simplies the operation o the control system. For example, i the eed fow to a column is controlled by a liquid level controller, that controller can be tuned with a low gain, (wide proportional band) so that the level will be allowed to swing over a wide range without causing much change in fow. Nevertheless, i the eed comes rom another column, the eed to the second column will eventually change i the load on the rst column changes. As shown in the control loop or Column A in Figure 14 (p.23), the temporary fow fuctuations rom the previous column and/or the pressure fuctuations caused by the distillate/refux pump can be minimized by cascading the eed-fow controller to a nonlinear level master (LRC) on a surge tank. Such level controllers can be so congured that as long as the level is between 25% and 75%, the set point to the FRC remains constant. Naturally, i the level drops below 25% or rises above 75%, the FRC set point is changed to protect the surge tank rom being drained or fooded. Feedback controls are capable o compensating or upsets only ater the upsets have occurred and been detected. With eedback controls, the operators have to manually adjust the set points o the loops when plant conditions change. Feedback control is usually sucient to keep the distillation column in operation, but it is not sucient to provide optimal perormance. Usually, eed-orward-based product composition control o distill ation can provide 5% to 15% energy savings. The goal o a eed-orward control application can be to maintain the material balance o the column as eed rate varies. Feed-orward controls represented the rst steps towards model-based process control. They were rst applied in well-understood processes, such as heat transer and distillation, where the rm knowledge o material and heat balance equations made it possible to predict and anticipate the consequences o changes in the inputs beore they had time to evolve, and to take corrective action beore the tower is signicantly a ected. This correction is accomplished by considering process dynamics (dead times and time lags), the nonlinearities between separation eciency and column loading, loop interactions and process measurements. I eed-fow variations are unavoidable, the impact o these disturbances can be reduced by eed-orward correction o the material balance (Column B in Figure 14). In this conguration, i the distillate fow is changed in the right proportion (m) and at the right time, the upsets resulting rom eed-fow variations can be minimized. This dynamic compensation (FY ) is not only a ratio adjustment, but must also be tuned to refect the time constant and dead time o the process. However, i the eed composition changes, the value o m will have to be readjusted. mxg h Fd Fw

In cases where both the demand or the product and the availability o eedstock is unlimited, increasing the throughput o the column maximizes protability. In such installations, a valve-position controller can be cascaded to the eed-fow controller in order to increase the eed rate until an equipment constraint is reached. In many cases, it is not known which constraint will be encountered rst, as eed fow is maximized because the limiting constraint may vary over time. In such cases, a multiple constraint network is implemented. In such a conguration, the outputs o the valve-position controllers (VPCs) detecting the loadings o the critical equipment are sent to a low-signal selector, and the eed fow is set by that. I the constraint on maximum production is the cooling capacity o t he condenser, the opening o the columnpressure control valve can be measured (VPC on Column C in Figure 14), and the eed rate can be manipulated by the valve-position controller to keep t he back-pressure control valve always nearly open (V PC set at 90%). I a hot-vapor bypass around the condenser exists, as is the case on Column C, the opening o the bypass valve can also be used to indicate the condenser load. www.controlglobal.com

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I the const raint on maximum production is the heating capacity o the reboiler, a similar cascade control coniguration can be used to keep the reboiler ully loaded (Column D, Figure 14). This strategy is particularly e ective when the cost o reboiler heat is negligible, such as when a waste steam is used t hat otherwise would be vented. The VPCs used on Columns C and D are usually selected as integral-only controllers and are set at around 90% o valve stem lit, which on an equal-percentage valve corresponds to about 70% o maximum fow. The integral time setting o the VPCs is slow, about 10 times the integral setting o the FRC, which the VPC adjusts in a cascade arrangement. In order to eliminate reset windup, the VPC is provided with external eedback (FB) rom the slave transmitter (FT, the eed-fow transmitter). FiGure 14

Nonlinear Distillate

LRC

LT

Set FRC

A

B

FT

FT

X

SP m

Feed

Set @ 90% INT.

Back-pressure valve Maximum coolant flow rate

VPC

FB

PRC

F

LRC

FRC

FT

PRC

PT

FB

L LRC

Set (F) FRC

FT

FC

FY

C

FRC

FRC

Set (Q)

INT

FRC

D

VP C

Set (F)

Heat (Q) FB

Set (D)

B FRC

D

F B

TRC

To column

PID FRC

TT

Economizer

E

Set

T F

F

F

TT

FT TRC

Steam VP C

SP

FB Reboiler

Feed INT. set @ 10% bypass

Fd control systms. A: Surg t ank with non-linar lvl controllr as cascad mastr; B: Fd-orward adjustmnt o distillat product fow; C: Maximizing throughput by ully loading th condnsr; D: Maximizing throughput against a rboilr constraint; e: Fd pr-hatr controls; F: Maximum rcovry o th hat contnt o bot tom product by conomizr.


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Fd t d ehy C

The thermal condition o the eed determines the required heat input at the reboiler, but constant temperature alone does not necessarily mean constant eed quality. For best separation eciency, the eed should be preheated to its bubble point (the temperature at which bubbles rst appear when a liquid mixture is heated—when the lightest component in the eed starts to boil). I the composition o the eed varies, its bubble point will also vary. As the eed becomes lighter, some o it will vaporize, but this variation can be handled by subsequent controls. The controls shown or Column E in Figure 14 show the cascade controls or a steam-heated preheater. In this conguration, the temperature controller usually is a three-mode (PID) controller. The role o the derivative mode (D) during start-up is to provide a large correction initially, which helps to quickly get the unit up to stable operation. An economizer can be used to preheat the eed by sending it through an economizer (Column F, Figure 14), which is heated by the bottoms product. The economizer operation is optimum when the amount o heat recovered rom the bottoms product is maximized. To achieve this goal, a valve position controller (VPC) is used as the cascade master o the eed temperature controller, which controls the bypass around the economizer. The goal o optimization is to keep the bypassed fow at a minimum. Thereore the VPC is usually set at about 10% o valve opening. Control o eed enthalpy instead o temperature can be achieved i the right measurements are available. For example, i the cold eed (at temperature T F ) rst passes through the bottoms-to-eed economizer and then through the steam preheater, one can calculate the steam fow required to maintain t he eed enthalpy constant by the calculation: S = [F( ∆HF ) – CPFT F) – B(CPB ∆T )]/ ∆Hstm

Where: ∆HF = F = S = CPF = T F = B = CPB = ∆T = ∆Hstm =

eed enthalpy as it enters the tower, BTU/lb (kcal/kg) eed fow to preheater, lb/hr (kg/hr) steam fow, lb/hr (kg/hr) eed heat capacity, BTU/lb °F (kcal/kg °C) eed temperature beore preheaters, °F (°C) bottoms fow to economizer, lb/hr (kg/hr) bottoms heat capacity, BTU/lb (kcal/kg) bottoms temperature dierence through the economizer, °F (°C) steam heat o vaporization minus condensate heat, BTU/lb °F (kcal/kg °C)

The primary eect o increasing eed enthalpy is to decrease vapor-liquid circulation below the eed tray relative to that above the eed tray. When preheating the eed is less expensive than reboiler heat, or when the reboiler is the limiting constraint on production rate, the process is optimized by maximizing eed preheat. When condenser capacity is limiting or fooding is encountered above the eed tray, preheat should not be used.

reFluX Controls Stable column operation is guaranteed by keeping the internal refux o the distillation tower constant. Consequently, internal refux controls are designed to compensate or changes in the temperature o the external refux caused by ambient conditions. Column A, Figure 15 (p. 25) is controlled by a typical internal refux control system. The equations or calculating the required external refux rate are shown at the bottom. This control sy stem corrects or either an increase in overhead vapor temperature or a decrease in external refux liquid temperature and, obviously, the required control actions are in the opposite direction. www.controlglobal.com

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The need or internal refux control can be eliminated in some cases when the fow o disti llate product is controlled under the cascade control o the accumulator level. I the speed o response o this control system is not sucient, it can be speeded up by reducing o the accumulator volume. To overcome the accumulator lag, the refux rate, L, is manipulated in direct proportion to a change in distil late rate, D, rather than by waiting or the response o a level controller. In the control system or Column B, Figure 15, when K = 0, the refux is adjusted by the level controller only. In other cases, the refux fow is immediately altered by some percentage or a change in distillate, and the level controller orces the balance o the change. The response is a rs t-order lag. I K = 0.5, the refux fow is changed to the exact new steady-state value, because K equals the ratio o Dmax/Lmax, and thereore the computation is exact. The lead equals the lag and the net eect is the elimination o dynamic contribution. I K = 1.0, the initial response is a rst-order lead-lag unction. In this case, the refux is greater than required or the new steady state, and the level controller eventually corrects the fow. The value o K aects the transient response only, but does not change the steady-state fow; thereore, it can be used to adjust the dynamics o the loop. The greater the value o K the aster is the response. In order to maintain stability, K should not be set greater than 0.75. FiGure 15

T

V

O

TT X FRC

UY

∆

B

TY

A FT

FY

TT

L ∑ FIC

SET

L=m–KD

–K D

+m LT

FY

T

FY

LIC D

F

FY

X FY

K

FIC

FT

150-250ºF=0-100% T TT O

FT

D

125-225ºF=0-100% C X L =L(1+ p ∆T) ∆ T –T T i F o F ∆H TT TY UY [Li’=0.754L’(0.885 +0.115∆T’)] 0-50ºF=0-100% 0-10,000 GPM FT

L2

FY

L

Lt: Th controls rquird to kp th intrnal rfux fow o th column constant; Right: Th controls ndd to liminat th ct o accumulator lag in controlling th xtrnal rfux to a column.

p 3 ControllinG tHe WHole Column reviously, I have discussed the individual loops used to control the dierent segments o the distillation process. Now I will talk about various control strategies that can be used to control and optimize the complete column. Here, I will treat distillation as a single unit operation. In unit operations’ control, the individual column variables are treated only as constraints and so long as the values o these constraints are within acceptable limits, the column is controlled (optimized) to maximize production rate, protability, etc. In order to optimize the unit operation o distillation, one not only wants to keep the top and bottom product compositions within specication, but might also want to maximize the throughput, minimize energy use, enhance column stability or operate against equipment constraints. In addition, one might shit less protable components into more protable products. To optimize the protability o the operation, one must know the acceptable variations in product specications, the relative economic values o the product streams and cost o energy used in the separation.

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V, y

F L 2

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2

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FT FY LC

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Impulse

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Lag

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Top: Fd-orward co ntrol sys tm that provids c onstant spara tion by manipula ting th dis tillat f ow. Bottom: A varit y o dynamic compnsators that can b usd to matc h th “dynamic prsonality” o th procss. www.controlglobal.com

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Economics o individual ractionators may continually change throughout the lie o the plant, because energy savings can be important at one particular time, while product recovery can be more important at other times. Other goals include the desire to minimize the disturbances propagated to downstream units, minimize rework or recycle o o-spec products and maximize the consistency o product quality. Thus, a given column’s operating economics, and, thereore, its optimization objectives may change with time.

Constant separation A distillation column operating under constant separation conditions has one ewer degree o reedom because its energy-to-eed ratio is constant. This means that or each concentration o the key component in the distillate, a corresponding concentration exists in the bottoms. Thereore, i the eed composition is constant, and i the concentration o a component in one product stream is held constant, that xes the concentration o that component in the other. Figure 16 (p. 26) shows a eed-orward control system or constant separation in which distillate is the manipulated variable. The control system is so adjusted that the output (m) o the trim analyzer controller ARC is 50% when the design or normal distillate-to-eed ratio is required. I the gain o the multiplier ( FY ) is set at 2, the output tracks the load when this normal distillate-to-eed ratio occurs. The block labeled “dynamics” in Figure 16 is a special module that serves dynamic correction by modiying the transient response. This matches the time response o the distillate to a eed-rate change. The dynamic block most oten is a combination o a dead-time and a lead-lag module in series, which in the steady state makes no correction at all; its output equals its input. Because the “dynamic personalities” o the various dist illation processes are dierent, a variety o dynamic compensators are available to match them, as shown at the bottom o Figure 16. mx rcvy

I one product, such as the distillate ( D), is worth much more than the other, the control system can be designed to maximize the more valuable stream. I we assume that energy is ree, the material balance or distil late in such a column can be expressed as D = m(KF + K 2F2 ) where: D = distillate rate F = eed rate K = adjustable coecient K2 = 1 – K m = eedback trim Figure 17 (p. 28) shows the controls or this maximum recovery system. In this conguration, the boil-up (heat input rate) is constant, and consequently the distillate product fow is not linear with the eed rate. To increase the response o the system (minimize accumulator lag), the refux fow set point is adjusted by the distillate fow measurement. A summing block (FY-1) is provided to compute ( KF + K 2F2). The values o m can be calculated on the basis o eed composition. A typical range or m is 0.35 to 0.65. This is the output signal range o the eedback controller (ARC-2). While the coecients can be calculated with reasonable accuracy, online adjustment is also easy. (These coecients are accessible in most DCS and PLC systems.) I energy is not assumed to be ree, and the composition o only one product needs to be controlled, then the distillate fow can be determined by the ollowing linear relationship: D = m1(K3F). C C  tw pdc

I the composition specications or both products are tight, the controls described in Figure 17 (or the constant separation strategy) are not good enough. This is usually the case whenever the eed composition is unpredictable. In such cases, one must directly control the compositions o both products. The main benet o dual composition control is minimized energy consumption. The main limitation is caused by the severe interactions between the two composition loops. Naturally, the eed composition and the tower design determine the compositions that can be achieved. The let side o Figure 18 (p. 29) gives an example o a eed-orward dual composition control system. In this conwww.controlglobal.com

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KF + K 2 F 2

D = m (KF + K 2 F 2 )

D

L IC X FY

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ARC 2 LT ∑ FY 1

AT

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F

FY

F Y

V

√

F Y

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√

SP

FR C

L

FT

FT D F

Q

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Control systm that guarants th ma ximum rcovry o th mor valuabl product, in this cas, th distillat (D).

guration, the distillate fow is manipulated to control distillate composition by maintaining the relationship D = F [(z-x) / (y-x)]. However, in order to also enorce composition control o the bottom product, an additional manipulated variable is needed. This cannot be another product stream, because that would confict with the material balance and change the accumulation in the column. Consequently, the bottoms composition ( x) has to be controlled by manipulating the energy balance o t he column. The relationship between separation ( S) and the ratio o boil-up to eed ( V/F ) over a reasonable operating range is V/F = a + bS, where a and b are unctions o the relative volatility, the number o trays, the eed composition and the minimum V/F. The control system thereore computes V based on the equation V = F(a + b[V/F]), where [V/F ] equals the desired ratio o boil-up to eed. www.controlglobal.com

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L = K 1Q – K 2F

z–x D = F(m) = F ( ) y–x FY

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F FY

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+ K 1Q Q

– X

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(V/F) min + (V/F)

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Dynamics FY

√ FT

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Dynamics K 2

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Q = kF ([V/F] min + [V/F])

Dynamics

F m 2

∑

LT

AR C

Q

√ FY

FT

Q

AT

Q AR C

LI C

AT

B,x

B Lt: Conguration or controlling th composition o both products o a distillation column without much intraction; Right: With intraction.

The column on the let side o Figure 18 illustrates how the two product composition controllers (ARC) are congured to throttle the material balance (D) and energy balance ( V ) to maintain the compositions o both products. The loops include multipliers (FY-1 and FY-2) and the FY block labeled “dynamics.” This last block serves the unction o dynamic compensation, the role o which has already been explained in connection with Figure 16. tw pdc wh ic

Interaction is unavoidable between the material and energy balances in a distillation column. The severity o this interaction is a unction o eed composition, product specication and the pairing o t he selected manipulated and controlled variables. Severe interaction is likely to occur when the composition controllers o both products are congured to manipulate the energy balance o the column. An example o such a case is when refux fow and steam fow are manipulated by the two product composition controllers (Figure 18). In such cases, the heat input is Q = kF([V/F]min + [V/F]) while the refux rate is L = K1Q – K2F. Thereore, both product fow rates are dependent on energy balance terms. This conguration, without decoupling, results in severe interaction, because i the composition controller on the bottom product is increasing heat input to the reboiler, this action will orce the overhead composition controller to increase refux fow in order to increase heat withdrawal. Thereore the two composition controllers “ght” each other. In the decoupling equations just dened, the values o K1, K2 and k are determined by using the actual process values o [L/F], [V/F]min and [V/F]. The decoupling scheme shown on the right side o Figure 18 serves to minimize the tendency o a change at one end o the column upsetting the controller at the other end by implementing the decoupling equation L = K1Q – K2F. The system is now hal-decoupled: A change in heat input at the bottom will not upset the top composition, because the decoupling loop adjusts the refux independently. However, the heat input is still coupled to refux, because a change in refux will still cause the bottom temperature controller to adjust steam fow. This type o hal-decoupling is enough to reduce the interaction approximately twenty-old. The limitations o decoupling include the act that overrides can drive the loops to saturation when conwww.controlglobal.com

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straints are encountered. Also, in some distillation columns, small measurement errors can transorm a system that provides complete decoupling into one that provides no control at all. Since the proper decoupler gains (K1 , K 2 and k) depend on the process gains, and because process gains inevitably change with variations in eed rate, product specications and column characteristics, these systems require constant attention and adjustment. Such adjustments are beyond the capability o the average plant operating personnel and require sophisticated column models. The diculties associated with the application o decoupling systems have prompted a re-examination o interaction itsel. The problem may be postulated in two ways: 1) For a given column, is the interaction equally strong in each o the possible control congurations? 2) For a given control conguration, will the interaction be the same or every column to which it is applied? Some o the answers to these questions appear in the earlier discussion o relative gain calculations. One general rule worth remembering is that the composition controller or the component with the shorter residence time should adjust vapor fow, and the composition controller or the component with the longer residence time should adjust the liquid/vapor ratio. Fd C C

I the changes in eed composition occur too ast to be handled by eedback control, eed-orward compensation is required. I z is the concentration o the key component in the eed, the material balance, solved or disti llate FiGure 19

D = zF/m

x & ÷ z

FY

m

F ARC FY

Dynamics HIC

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1

LT

FY

SP L

AT

LIC

FY

FRC

FT FT

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Ratio controller

D

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Q B

Fd composition basd d-orward control o distillation. www.controlglobal.com

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fow is D = F [(z-x) / (y-x)], and thereore, when z is measured, the equation or distillate can be simplied to D = zF/m, where m is the output o the overhead analyzer eedback trim controller (ARC-1 in Figure 19, p. 30). The auto manual station (HIC) is used in the event o analyzer ailure. Dynamic compensation is included ( FY ) in the measurement o the eed fow ( F). The control o the bottoms fow (LIC) is indirectly obtained by the eedorward control o the reboiler heat input, which is also based on the dynamically compensated eed fow rate.

multiple proDuCt Distillation Most separations involve multiple components and produce two or more liquid or vapor products. Sometimes only one product is withdrawn at a time. When there is a side-stream product in addition to the overhead and bottom products, an additional degree o reedom is available or the control system, because the overall material balance becomes F = D + C + B, where C is the side-stream fow rate. Thereore, two product streams can be manipulated to control variables, while the material balance can stil l be closed by the third product fow. The presence o this added degree o reedom makes the careul analysis o the process even more essential to avoid mismatching o the manipulated and controlled variables. I the eed rate and column pressure are constant, ve degrees o reedom exist: three composition specications and two levels. These ve controlled variables can manipulate the material and heat balance by throttling three product fows and the loading o two heat exchangers (V and L). As was detailed in Part 1, interactions among the loops can be minimized by determining the relative gains o the possible combinations o the manipulated and control variables. Ater such evaluation, one might arrive at the controls shown on the let side o Figure 20 (p. 32). Here the ratio o heat input to eed and, thereore, boil-up to eed, is held constant, and separate dynamic elements are used or the distillate loop, the heat input and the side-stream loops. Multi-product ractionators—crude towers, vacuum towers and FCCU main ractionators—are common in the rening industry. Product quality is oten based on true boiling point (TBP) cut points, which approximate the composition o a hydrocarbon mixture and are numerically similar to the American Society or Testing and Materials’ 95 percentage points. As was shown in Figure 7 (p. 12), an articial neural network can calculate—on the basis o local temperature, pressure, steam fow and refux data—the 95% boiling point or TBP cut point o the products. I there is a boiling point analyzer, the ANN-based approximation can be used as the measurement or a ast inner slave loop o a cascade conguration in which the analyzer provides the measurement or the slower master, which trims the set point o the slave. Because o the volume o liquid/vapor loads within most multi-product ractionators, the greatest control sensitivity and the quickest response are usually obtained by thrott ling the product fows. Heat balance is oten controlled by throttling the pump around refux fows, as shown on the right side o Figure 20. The goal is to maximize the amount o heat that is transerred to the eed. Super-ractionators are used to separate st reams with close relative volatilities o the light and heavy key components. These include deisobutanizers, which separate isobutane rom normal butane, propylene splitters, which separate propane rom propylene, ethylbenzene towers, which separate ethylbenzene rom xylene, xylene splitters, which separate para and ortho-xylene rom meta-xylene. Super-ractionators require many trays; thereore, the column heights oten necessitate dividing them into two or even three sections. Super-ractionators require high internal vapor and liquid rates and high fow ratios o both refux-to-distillate and vapor-to-bottoms. These result in large tower pressure drops, long time constants and long dead times. Thereore, the response o compositions to the manipulation o eed and refux fows is slow. As a consequence, dynamically compensated material balance control is recommended to control the distillate compositions. mvb C

Traditional PID controls usually implement SISO (single input, single output) algorithms, while advanced controls work with multiple inputs and outputs (MIMO). The modeling o a process can be o the “white box” or “black box” type. White-box modeling is used or well-understood processes, such as distillation, where the knowledge o mass, energy and momentum balances allow the development o acwww.controlglobal.com

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Distillation Control & optimization FiGure 20 SP FT

FRC

D PRC SP

LI C

LT

PT

X

SP

F Y

FI C

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Dynamics F,z1 ,z 2

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Lt: Multi-product ractionator controls whr, atr dynamic corrction, th boil-up (V), sid-draw (C) and distillat (D) fows ar ratiod to th d fow (F ); Right: Th tru boiling points ar controlld by throttling th product fows, whil hat balanc is controlld by manipulating th rfux fows.

curate dynamic models. These internal model control (IMC) systems are useul in optimizing the process and in anticipating uture events. “Black box” or model-ree controls (MFC) include the ANN, uzzy logic and statistical process control strategies. These algorithms are trained on the data obtained rom the past operation o the controlled process. Their limitations include their required relatively long learning periods and the act that their knowledge is based on the past. Thereore, they are not well-suited to anticipating uture events, and i conditions change, they require retraining. md-Bd C

Once a process model has been established, it is possible to build the inverse o that model, which can be used as a controller. In that sense, the PID controller is a li near inverse model o a single process loop. A simple IMC is shown at the bottom o Figure 21 (p. 33). It has the same structure as a Smith predictor (Figure 9, Part B, p. 15), which is a rst-order system with dead time combined with a PI controller. Multivariable control (MVC) is particularly well-suited or controlling highly interactive ractionators, where several control loops need to be simultaneously decoupled. Figure 21 illustrates an MVC conguration, which simultaneously considers all the process lags and applies saety constraints and economic optimization actors in determining the required manipulations to the process. In Figure 21, two products and an impurity stream are produced by two towers. The objective is to control the composition o both products; thereore, when an adjustment is made to control one composition, that manipulation causes a disturbance in the operation o t he other composition loop. In this example, the MVC controls the two product compositions, while keeping the operation within the constraints o the process equipment capacities and considering the dead time introduced by the stripper. In this process, the eed-fow rate is the main dist urbance variable. The steam to the rst column and the temperature at the top o that column are the manipulated variables. A constraint vari able is the internal refux fow, which is calculated rom tower temperatures and fows. www.controlglobal.com

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The technique o multivariable control requires the development o dynamic models based upon ractionator testing and data collection. Multivariable control applies the dynamic models and historical inormation to predict uture ractionator characteristics. Predicted ractionator responses result in planned controller actions on the manipulated variables to minimize error or the dependent controlled variable. For towers that are subject to many constraints, towers that have severe interactions, and towers with complex congurations, multivariable control can be a valuable tool. FiGure 21

PI C

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Multivariabl intrnal modl controls (IMC) or controlling two product compositions (B), whil kping th opration within th constraints o th proc ss quipmnt and whil taking into account intractions and th dad tim introducd by th s trippr.


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Dynamic Matrix Control (DMC) is also an MVC technique, but it uses a set o linear dierential equations to describe the process. The DMC method obtains its data rom process-step responses and calculates the required manipulations using an inverse model. Coecients or the linear equations describing the process dynamics are determined by process testing. During these tests, manipulated and load variables are perturbed, and the dynamic responses o all controlled variables are observed. This identication procedure is time-consuming and requires substantial local expertise. afc n nwk

Figure 22 (p. 35) shows a three-layer, back-propagation ANN, which predicts the manipulated steam and refux fows o a column. The process model is stored in the AN N by the way its processing elements (nodes) are connected and by the importance that is assigned to each node (weight). The ANN is “trained” by example, and thereore, it contains the adaptive mechanism or learning rom examples (somewhat similarly to the learning process o a child). During the “training” o these networks, the weights are adjusted until the output o the ANN matches that o the real process. Naturally, when process conditions change, the network requires retraining. The hidden layers help the network to generalize and even to memorize. In the SISO conguration, the ANN network builds an internal nonlinear model relating the controlled and manipulated variables. It builds this model by learning or “training” rom a data set o known measurements and process responses. This makes the neural controller more useul and more robust than the standard PID. Because the neural network paradigm can accommodate multiple inputs and outputs, an entire ractionator model can be built into a single controller. The neural controller can be thought o in t he same terms as model-based control algorithms, whereby the neural network is used to obtain the inverse o the process model. As shown on the top right o Figure 22, the back-propagation network can be trained to behave as an inverse model o the process, with load and controlled variables being input vectors and manipulated variables output vectors. To build such a model, all inputs and outputs must rst be normalized based upon expected minimum and maximum values, and be presented to the network or the t raining By using the same historical data, the network can be trained, and a nonlinear internal model can be created. The network’s ability to do the prediction o the dynamics o the ractionator improves as more data become available or training. Thus, the neural controller can be considered as a specic type o nonlinear, multivariable, model-based control algorithm. Instead o creating the nonlinear process model with explicit equations, the neural controller builds its own process model rom actual tower operation. Since the neural controller is an empirical, not a theoretical model, it is susceptible to errors i operated outside the conditions o the training set. Data or the training set need to be continually gathered and the network retrained whenever novel conditions occur in order to increase the robustness o the neural controller throughout its operating lie. th t md

It is possible to design a control system which will compensate or changes in any o the load variables: eed rate, composition, enthalpy, refux and bottoms enthalpy. The goal o these systems is to eliminate interactions and to protect the column rom the consequences o changes in ambient conditions. To provide a model t hat describes both the material and energy balance o the column, one has to develop both the steady-st ate and the dynamic equations or the ollowing: • Feed enthalpy balance, • Bottoms enthalpy balance, • Internal refux computation, • Reboiler heat balance, • Overall material balance. www.controlglobal.com

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B

Manipulated variables Stream flow (Q)

Reflux flow (L) Output layer Output node #2

Output node #1 W 1,4 W 1,3

W 1,0

W 1,2 W 1,1

Hidden layer Hidden node #1

Hidden node #2

Hidden node #3

Hidden node #4

Input layer

Bias Input node #2

Feed flow

Top temp Bottoms temp T Reflux temp o T Feed temp b T T

F

f

Input node #3

Input node #4

Input node #5

Input node #1

Input node #6

Bottoms composition

l

Disturbance variables

X

Input node #7

Distillate composition

Input node #8

Tower pressure

Y

Controlled variables

Th congur ation o a back-pr opagation nur al ntwor k (AN N) and its us a s an intrnal mod l controllr. www.controlglobal.com

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P


sb-o  u o

Every distillation column is unique and thereore, the control strategies described in Figure 23 (p. 37) are or illustrative purposes only and should not be considered to be the sub-optimal or optimal control solutions or every column. The goal o optimization o a single column is to saely operate at maximum prot, but this can only be done i the market value o each product is known. This is not t he case when the products o a column are not nal products, but the eed fows to other unit processes. When the product prices are unknown, it is still possible to perorm optimization, but the optimization goal changes. The criteria in t hat case becomes the generation o the required products at minimum operating cost. This can be called an optimum with respect to the column involved, but only a “sub-optimum” with respect to the system o which the column is a part. When the market values o the products are known, the column can be ully optimized, but additional variables, including the type o the market that exists or the products, must still be considered. I the market is limited, the goal is to generate the products at optimum separation and minimum operating cost. This cost varies as the eed fows and their compositions vary. When the market is unlimited and sucient eedstock is available, the optimization task is more dicult, because one must determine both the optimum separation and the value o the eed streams. In this case, the goal o optimization is either maximum loading or maximum energy eciency. In this case, one o three constraints can be the limiting one: 1. Throughput can be limited by t he maximum cooling capacity o the overhead vapor condenser, 2. The maximum heat input capacity o the reboiler, 3. The maximum separation rate o the column itsel. In some cases, this constraint will change rom time to time, depending upon product prices and other independent variables. Thereore, the design o an optimal control system or a single column should ollow three logical steps: 1. Designing the basic controls to regulate the operating variables, such as pressures, temperatures, levels and fows; 2. Conguring t he controls to regulate the reboiler heat input, the internal refux fow rate, eed enthalpy and the sources o heat to the reboiler and preheater(s); 3. Determining the controls required to maintain the specied separation. I the above control loops are provided or a single column, that column can be said to have been “sub-optimized.” This sub-optimum will generate products at close to the specied separation, whether or not that separation is ideal with regard to the total system. I product purities are higher than specied, the operation is not considered sub-optimum. og eq

When a single column is automated through the sub-optimum operation stage, it will still exhibit up to ve degrees o reedom. The let side o Figure 23 describes the controls o a column that has been “sub-optimized” by controlling bottom product fow to obtain the specied separation. Figure 24 (p. 38) shows some typical operating control equations used in operating the predictive controls or maintaining the energy balance (refux fow rate) and the material balance (bottom product fow rate) to give the specied separation (right o Figure 23). Both control systems shown in Figure 23 will achieve their goal o operating at sub-optimum; the dierence is mainly in their basic controls. The theoretical operating equations are normally developed by tray-to-tray runs o calculations, which are usually perormed by an o-line digital computer. Next, a statistically designed set o runs is made, and the inormation thus obtained is curve-tted to an assumed equation orm. Once the steady-state theoretical equation is developed and placed in service, the ex perimental part is determined by online tests. These tests involve operating the column at dierent loads to determine the correction required to (Li/F) in order to obtain the specied separation. Average overall eciency E is set to make ( Li/F) equal to the actual Li/F which exists. The loading tests are carried out under this condition. www.controlglobal.com

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Computer input ( T o - T ) r

Computer input ( T o - T ) r

TDT

TDT

Specify set ( PC )

Hot vapor by pass

PRC

T o FRC

Specify set ( PC )

PRC

T o

PRC

Set

FRC

T r

PRC

T r

LRC

Set

Hot vapor by pass

LRC

Steam

Set (D)

Top product

Reflux

FRC

Steam

D

Feed (F) Reflux

Feed (F)

FT

AT

Set (L)

D

AT

FRC

Computer inputs

LRC

Set

LLK F LK F HK F F

Steam

Set (B)

HK B FT ∆HF

Steam

FRC

Q

Internal reboiler

LK B HK B FT ∆HF P E

set point outputs (L1 T f B)

Bottom product operating equation and dynamics

LLK F LK F HK F F m

Measurements Computer

Measurements

E

Specified inputs

Computer

Computer

Reflux operating equation and dynamics

P

Set (D)

B

Internal reboiler

Bottom product

LK B

Set (L) Set (Q)

LRC

Bottom product

FRC

FRC

FRC

Set

FRC

Computer inputs

Specified inputs

Set (Tf)

LLK F LK F HK F F

Set ( T f )

FRC

TRC

Top product

TRC

B

FT

T O - T r

Feed enthalpy regulation

Top product operating equation and dynamics Reflux operating equation and dynamics Feed enthalpy regulation

m= Measurements required to compute feed temperature for specified value of feed enthalpy

m LLK F LK F HK F F T O - T r

Computer set point outputs

T f

L

D

L = external reflux flow rate K 1 = ratio of specific heat to heat of vaporization of the external reflux

where

K = ratio of heat vaporization of external reflux to heat of vaporization of internal reflux 2

%LLK F = lighter than light key in the feed (mol%)

T O = overhead vapor temperature

%LK F = light key in the feed (mol%) = z %LLK D = lighter than light key in the distillate product (mol%)

T = external reflux temperature r E = specified constant average efficiency

%LK D = light key in the distillate product (mol%) = y

FT = specified value of feed tray location

%HK D = heavy key in the distillate product (mol%)

∆HF = specified value of feed enthalpy

%LK B = light key in the bottoms product (mol%) = x

P = specified value of column pressure

Suboptimization distillation controls aimd at producing th spciid sparation by controlling bottom product low (lt) or r lux low (right).

In other cases, plant tests can be perormed to determine Li/F without consideration o the theoretical term. As to the internal refux fow rate, one can approximate it by making a heat balance around the top tray. I the operating equations that have been obtained or the steady state are used without alteration, the column will be upset when changes, such as sudden eed fow rate increase or decrease occur. Feed composition changes cause less severe upsets and, thereore, providing dynamic compensation is less o a concern. The purpose o dynamic compensation is to compensate or changes (such as eed-fow rate changes) in such a way that the column’s terminal fows respond to them at the proper time, in the correct direction and without overshoot. The simplest dynamic element, which can be used is the sum o a dead time plus a second-order exponential lag response. As shown in Figures 18 (p. 29) and 23, the eed fow rate signal is passed through this dynamic element beore being used to obtain the set points or the bottom product fow rate (B) and the refux fow rate ( L) set points. The bottoms and overhead dynamic constants, t, T 1 and T 2 in the operating equations listed in Figure 24, are not necessarily the same values. With the use o the operating equations in Figure 24 (p. 38), the system still has ve degrees o reedom. Thereore, eed tray location (FT ), eed enthalpy ( ∆HF), column pressure (P), concentration o heavy key component in the top product (%HKD), and concentration o light key component in the bottom product (%LKB ) can all be controlled according to specications. Although tray eciency is also included in the operating equations, it is a xed value. www.controlglobal.com

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FiGure 24

Column loading limited by condenser Set (P)

Maximum coolant flow

PRC

D

Set (T F )

(PD), (%LLK D ) ( %HK D )

L

TRC

(%LK D ) ≥ ( %LK D ) SS FRC

F Set

( L)

(FT) O

FRC

Set ( F)

Set

(B )

FRC

B (PB), (%HHK B ) ( %LK B ) F

P

T f

F T o

L

(%HK B ) ≥ ( %HK B ) SS

B

Setpoints (B)

(FT)O

( L)

( T 1 )

( P) O

Suboptimization operating equations: ( B) = ( F)

Ke – ts

(%HK D )

( %LK B )

For liquid phase feed 100 –

( T 1 s + 1) ( T s + 1) 2

(%HK D ) 100 –

–

(%LLK F )

(%HK D )

–

–

(%LK F )

(%LK B )

where ∆H F = Specified value for feed enthalpy ( CPF ) = Specific heat of feed

– ts

( L) = ( F)

( L 1 /F ) t – (L 1 /F ) e

Ke

( T 1 s + 1) ( T s + 1) 2

K 2 [1

+

( T f ) = Temperature of feed

K 1 ( T O – T t ) ]

( T ) = Base temperature of transmitter b

( ∆H F ) + ( CPF ) ( T ) b

( T 1 ) =

( CPF )

( ∆H F ) = ( ∆H F ) o

( P)O

(FT)O

for ( L 1 /F ) t

for (L 1 / F) t

Optimization equations (empirically developed) (FT) O = f 3 [ (%LLK F ) , (%LK F ) , (%HK F ) , ( F) , (%HK D ) , (%LK B ) ] ( ∆H F ) o = f 4 [ (%LLK F ), (%LK F ), (%HK F ) , ( F) , (%HK D ) ,(%LK B ) ] ( P)O = f 5 [ (%LLK F ) , ( %LK F ), (%HK F ) , ( F) , (%HK D ), (%LK B ) ]

( F)

(%HK D ) O

(%LK B ) O

( P) O

1. Determine optimum separation (%HK D ) O (%LK B ) O 2. Determine optimum column pressure, ( P) O 3. Determine feed flow rate set point, ( F) that will load overhead vapor condenser.

Values determined to give maximum profit

Top: Th cont rol congurati on; Bottom: Oprating quations to minimiz oprating cost s whn th markt is unlimitd and product prics ( PD & PB ) ar known. www.controlglobal.com

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total optimization Optimization implies maximum prot rate. An objective unction is selected, and manipulated variables are chosen that will maximize or minimize that unction. This is similar to the PID equation that is designed to minimize the error between the set point and measurement, but it views the process at a higher level. Optimization can be applied in several layers. Local optimization is the optimization o a single column. Normally, the goal o optimization o a single tower is to obtain minimum energy consumption or maximum throughput. For a detailed treatment o distillation optimization and o the development o the optimization equations, reer to Chapter 8.21, Vol. 2, The Instrument Engineer’s Handbook, 4th edition. Unit optimization addresses several columns in series or parallel. It is concerned with the e ective allocation o eedstocks and energy among the members o that system. Plant-wide optimization involves coordinating the control o distillation units, urnaces, compressors, etc. to maximize prot rom the entire operation. All lowerlevel control unctions respond to set points received rom higher-level optimizers. pdc-pc Cd

I the prices o the distillation products are not known, it is impossible to maximize the prot rate or that column without taking into account all other aspects o the overall plant. Optimization o a single column whose product prices are unknown involves determining the location o the eed t ray ( FT ), the eed enthalpy ( ∆HF), and the column pressure (P), which will result in minimum operating costs. Assuming that the appropriate operating equations are available, it is a relatively simple matter to establish optimum values or these t hree variables. Because these variables must stay within specic limits, a st atistical design study can be made ofine that allows correlation o the variables with each o t he three optimizing variables. In a majority o cases, the optimum column pressure ( P) can be ound by lowering the operating pressure until the condenser capacity is reached, or until liquid entrainment occurs in the vapor on the trays. The operating equations in Figure 24 are applicable or the case when product prices are unknown. When terminal product prices or a single column are known, the column is optimized to obtain the specied separation or the least operating cost. In this case, the main task is to nd the separation that will maximize prot rate. Any o the ollowing conditions can be true or a particular column. 1. The optimum separation can be determined independently o eed cost. 2. Optimum separation can be obtained by producing the product with the highest unit price at minimum specied purity. 3. The optimum separation is a unction o t he price dierence between products. 4. The optimum separation is a  unction o the price dierence between the heavy key components in the top and bottom (PHKD – PHKB) and o the price dierence between the light key component in the top and in the bottom products (PLKD – PLK B). The above our policies are derived by the evaluation o the partial dierential equations that describe the prot rate or a single column with respect to t he specied separation, noted as ( LK B), (HKD). og C

When product prices are known, complete economic optimization almost always requires that the column be operated against a constraint or at a point where the specied separation, ( LK B), is such that an incremental gain in production is equal to a corresponding incremental gain in operating cost. Column loading is increased when either the separation is improved or when the eed rate is increased at a constant separation. The operating constraints are a unction o the capacities o the condenser, the reboiler and the column. As eed rate or separation is increased, one o these three constraints will be approached. Ambient conditions, steam pressure, eed composition, etc. can also infuence the choice o the constraint rst reached. www.controlglobal.com

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Condenser Constraint: The maximum cooling capacity o a given condenser at maximum coolant fow rate is

a unction o the dierence between the temperatures o the overhead vapor and o the coolant. When operating against the condenser constraint, tests should be conducted to determine the maximum vapor fow rate as a unction o this temperature dierence. Such a correlation can be obtained by column testing. Column pressure and condenser ouling are also major variables that will aect overhead vapor temperature. Reboiler Constraint: The maximum heating capacity o the reboiler at maximum heating media fow rate is a unction o the temperature dierence between the heating media and the liquid being reboiled. As with the condenser, tests can be conducted to correlate maximum vapor fow rate with temperature dierence across the reboiler tubes. Column pressure and reboiler ouling are major variables that will aect this correlation. Generally, when using waste streams such as low-pressure steam that would alternatively be vented, it is optimal to operate against a reboiler constraint. Column Constraint: Column capacity is a unction o liquid and vapor fow rates and o column pressure. Oten, capacity is limited by liquid entrainment o the vapor. Operation at low internal liquid fow rates allows higher vapor fow rates. Also, column capacity increases as the operating pressure rises. I capacity is limited by entrainment, then loading can be increased by raising the operating pressure. However, i column capacity is limited by the tray downcomers, internal liquid fow rate can be increased by lowering pressures. Thereore, to optimize the operation, the capacity-limiting parameter must be known. An equation can be developed rom test data to cover a limited range o liquid and vapor fow rates and pressure. This relationship can be linear and have a orm o V max = a1 + a 2 (L) + a3 (P). This equation is useul in predicting the values o eed fow rate and o t he separation that will cause maximum vapor fow rate to exist. For a detailed description o optimization strategies or a variet y o product prices and market conditions, reer to Chapter 8.21, Vol. 2, The Instrument Engineer’s Handbook, 4th edition. Cc

The advanced process control strategies that are most applicable to the optimization o the distillation process are usually based on white-box modeling, where the theoretical dynamic models are derived on the basis o t he mass, energy and momentum balances o this well-understood process. Fuzzy-logic and black-box models are less oten used, as they are more applicable when it is acceptable to use a complete mechanistic empirical model constructed solely rom a priori knowledge. The amount o energy used or distillation is approximately 8% o the total energy used in the industrial sector o the United States. Reneries spend 50% to 60% o their operating costs (i.e., excluding capital costs and depreciation) on energy, almost twice as much as does the better controlled and optimized chemical industry (30% to 40%). This dierence shows the potential or saving s through better control and optimization. While the optimization techniques described in this book can improve renery productivity and protability by 25% compared to present operation, this goal will only be achieved i we stop using individual PID loops and treat distillation as a single and integrated unit operation. In multivariable unit operation control, the variables, such as fows, levels, pressures, etc. become only constraints, while the controlled and optimized variable is productivity and protability. The advances in process control have replaced or supplemented the single loop PID, but it is still true that we can only control a process i we ully understand it. As was explained, each distillation column has its own “personality” and one cannot control it without ully understanding it. Thereore, the importance o the role o process control engineers, who ully understand the controlled process did not diminish, but in  act increased in C importance as our tools o control became more sophisticated. www.controlglobal.com

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Acronym references ANN – ar ticial nur al ntwor ks ARC – analy zr rcor ding controll r B – bottoms product CW – cooling watr D – distillat DMC – dynamic matrix control e – cincy FCCU – fuidizd catalytic cracking unit FRC – fow rcording controllr FT – fow transmittr or d tray HK – havy ky HHK havir than havy ky IMC – intrnal modl control L – rfux Li – intrnal rfux LK – light ky LLK – lightr than light ky LNG – liqud natural gas LRC – lvl rcording controllr MFC – modl-r controls MIMO – multipl input, multipl output MVC – multivariabl control PB – pric o bottom product PCV – prssur control valv PD – pric o distillat PI – prssur indicator PIC – prssur indicator controllr PID – proportional-intgral-drivativ PRC – prssur r cording controllr RFC – rfux fow controllr RIC – r atio indicating controllr RG – rlativ gain SISO – singl input, singl output TBP – tru boiling point TRC – tmpratur rcording controllr VPC – valv posit ion controll r VPCV – valv pos ition contr ol valv ∆H – nthalpy chang x – bottom pr oduct compos ition y – distillat composition z – d composition


– 1 –

According to Lipták, developing eective control strategies and optimization o distillation columns can improve “productivity and proitability by 25%.” Being able to test these control strategies and optimization techniques oline can provide additional signiicant savings in time and money. By using the MiMiC Distillation Modeling Package, the process or instrument engineer can: • Test control strategies and optimizations on an accurate, dynamic plant model • Optimize the operation o the distillation process

• Train operators ofine in an environment identical to plant Human Machine Interace

The MiMiC Distillation Modeling Package is a powerul tool or control strategy testing, initial and ongoing tuning o control loops, and dynamic optimization o distillation systems. It provides dynamic and accurate models or distillation, providing time and cost savings to maximize new capital projects and operational excellence initiatives. It provides: • Accurate dynamics or distillation simulation • Easy-to-use conguration wizard tool • Powerul data visualization tools • Quick and easy integration with process automation systems through MiMiC simulation tags

For more inormation about the MiMiC Distillation Modeling Package, please contact: MYNAH Tchnologs 504 Trad Cntr Blvd. Chstrld, MO 63005 USA +1.888.506.9624 (North Amrica) +1.636.681.1555 (Intrnational) +1.636.681.1660 (Fax) http://www.mynah.com

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Liptak Distillation eBook

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