The present invention is a method for analyzing a small hydrocarbon sample to determine the composition of the sample. In particular, the sample is analyzed by a gas chromatograph and field ionization time of flight mass spectrometer.
Petroleum samples are complicated hydrocarbon mixtures containing paraffins, cyclic paraffins, multiring aromatics, and various heteroatomic hydrocarbons (most commonly O, S, and N). Virgin petroleum crude oils contain molecules of a wide boiling point range from highly volatile C4 hydrocarbons to nonvolatile asphaltenes. Analysis of petroleum composition of various boiling ranges is necessary for inputs to many subsequent processes.
The present invention is a method to determine the composition of a hydrocarbon sample. The method includes the steps of analyzing the sample with a combination of chromatograph and mass spectrometer, and reconciling the output with other analytical measurements to generate a self-consistent model of composition of the said hydrocarbon sample.
In a preferred embodiment, the combination of the chromatograph and mass spectrometer is a gas chromatograph field ionization time-of-flight mass spectrometer (GC-FI-TOF-MS). The data from the mass spectrometer is then reconciled with other analytical measurements, such as those from super critical fluid chromatography (SFC), sulfur simulated distillation (SIMDIS), simulated distillation (S-SIMDIS), N and S elemental analysis, 1H-NMR and GC-Flame Ionization Detection (FID) for normal paraffins. The reconciled data gives a detailed identification and quantification of petroleum compositions (referred to micro-hydrocarbon analysis, MHA) which are used as input for modeling of petroleum refinery processes.
a shows the cumulative weight percent distilled off as a function of boiling point.
b shows the cumulative target distribution versus calculated distribution as a function of boiling point.
c shows
as a function of boiling point.
Molecule Management has become increasingly important in petroleum research, refinery processing, and raw materials evaluation. Molecular compositions of crude oils and intermediate refinery streams are key input parameters to Structure Oriented Lumping (SOL) process models, Optimizable Refinery Models (ORM's) and Real Time Optimization (RTO) Models. In addition to guiding commercial selection of crude oils and refinery processing conditions, these models have become useful for both guidance and development of R&D programs. Molecular composition has become the basis for developing the current process models and evaluating the economic value of crude oils. The current art of obtaining petroleum composition involves various stages of distillation and fractionation followed by detailed analysis. Unfortunately, small sample size and need for quick results can be a significant barrier for applying the current state of the art analysis. For example, Advanced Catalyst Evaluation (ACE) pilot units used in catalytic cracking research routinely generate less than 1 gram of total liquid product (TLP). Even when sufficient volume of sample is available for the traditional characterization, it is a time-consuming process that limits the rate at which samples can be analyzed.
Micro-Hydrocarbon Analysis (MHA) consists of two components as illustrated in
I. Measurement of Composition by GC-FI-TOF Mass Spectrometer
GC-FI-TOF mass spectrometer is the core component of Micro-Hydrocarbon Analysis. In this technique, GC is used to separate hydrocarbon species by boiling point or polarity depending on type of column used. The technique applies to a wide boiling point range as demonstrated in
Quantification of GC-FI-TOF data is carried out in two ways. First response factors of carbon numbers (or molecular weight) were determined using a mixture of alkyl benzene standard (C7 to C25). Second the total Hydrocarbon classes, paraffins, naphthenes, 1-ring aromatics, 2-ring aromatics and 3-ring+aromatics were normalized to that determined by high-resolution supercritical fluid chromatography or other chromatographic techniques.
Reduction of GC-FI-TOF data is based on defined retention time window and accurate mass window for various hydrocarbon species. The measurement generates a composition that will be further reconciliated with other analytical measurements.
Long term repeatability of MHA was studied on both alkyl benzene standard and on total liquid products from Catalytic Cracking experiments. Field Ionization is the major source of uncertainty in GC-FI-TOF measurement. FI sensitivity varies with molecular weight and molecular types. It also depends on the type of emitters used in the experiments. For practical applications, a mixture of alkyl benzenes (C7 to C25) are analyzed before and after a series of sample runs. In addition to calibrate carbon number response factors, the analysis also corrects fluctuations in GC retention time and MS measurement.
II. Reconciliation of GC-FI-TOF Mass Spectrometer Data
The final step of Micro-Hydrocarbon Analysis is to reconcile analytical measurements to the model-of-composition. In particular, the model-of-composition must reproduce all measurements in the analytical protocol as closely as possible, and at the same time satisfy a set of property balances, e.g. mass and is elemental composition. A number of targets were used for the data tuning (or data reconciliation). The total olefin content is tuned to that measured by proton NMR. Hydrocarbon and S yields were tuned to that measured experimentally by gas chromatography simulated distillation (SIMDIS and S-SIMDIS), calculated N and S contents were tuned to that measured by elemental analysis, etc.
One embodiment of this reconciliation procedure is to treat it as a constrained optimization problem: we optimize the model-of-composition's fidelity to the test results of the analytical protocol subject to the property balance constraints. Another embodiment of the reconciliation procedure is successive substitution, an iterative procedure in which the model-of-composition is adjusted to match the results of the analytical protocol in a prescribed sequence until changes in the model-of-composition between iterations fall below a prescribed tolerance. The detailed description of model of composition and data reconciliation can be found in the attached appendix.
III. Generation of Cut Composition from MHA
One significant advantage of MHA is that it enables the generation of boiling point cut composition without physically distilling the sample. Tables 4 and 5 show the compositions of naphtha and middle distillate predicted by MHA virtual cut (cut based on calculated boiling point of the molecules) and that based on measurements of physically distilled cuts. The results agree well.
The Model-of-Composition
1. Introduction
Petroleum streams are complex mixtures of hydrocarbons containing many thousands of distinct molecular species. These streams include any hydrocarbon stream from processes that change petroleum's molecular composition. The streams are so complex, and have so many distinct molecular species that any molecular description of the composition is essentially a model—a model-of-composition.
2. Organizing the Model-of-Composition
The model-of-composition is organized initially into four major groups: saturates, aromatics, sulfides and polar molecules. Olefins are rare in crude petroleum, but are generated in refining processes that involve thermal or catalytic cracking and comprise a fifth major group. Within each major group, we organize molecules by homologous series. A homologous series is a molecular group that shares the same chemical structure (core), but has alkyl side chains of differing carbon number, arrangement and branching patterns.
It is convenient to organize hydrocarbon homologous series by hydrogen deficiency. Hydrogen deficiency can be organized into 14 classes (the primary x-classes) according to the formula:
x-class=(−14)+mod(MW,14). 1.
The x-class is the remainder of the “nominal” molecular weight divided by 14. By convention the values −12, −13, −14 are replaced with 210 so x-class runs from −11 to 2. Although several homologous series present in petroleum share the same x-class, all molecules within each homologous series share the same x-class because the molecular weight of a —CH2— group is 14.
Saturate Molecules
Saturate molecules contain only aliphatic carbons and hydrogen and their x-classes take the even integers −12, −10, −8, −6, −4, −2, 02.
Aromatic Molecules
Aromatic molecules have carbon atoms in aromatic rings. Aromatic molecules found in petroleum often contain sulfur and non-basic nitrogen (—NH—) groups. We have organized aromatic molecules by ring class, i.e. 1, 2, 3 and 4+.
1 Ring Aromatic Molecules
2 Ring Aromatic Molecules
Two ring aromatic cores shown in
3 Ring Aromatic Molecules
4 Ring Aromatic Molecules
4 ring aromatic cores shown in
Sulfide Molecules
Sulfide molecules contain aliphatic sulfur, but they have neither oxygen nor nitrogen. The cores shown in
Polar Molecules
Polar cores shown in
Olefins and Thiophenes
Olefin and thiophene cores shown in
3. Reconciling Analytical Measurements to the Model-of-Composition
The final step of Micro-Hydrocarbon Analysis is to reconcile analytical measurements to the model-of-composition. In particular, the model-of-composition must reproduce all measurements in the analytical protocol as closely as possible, and at the same time satisfy a set of property balances, e.g. mass and elemental composition.
One embodiment of this reconciliation procedure is to treat it as a constrained optimization problem: we optimize the model-of-composition's fidelity to the test results of the analytical protocol subject to the property balance constraints. Another embodiment of the reconciliation procedure is successive substitution, an iterative procedure in which the model-of-composition is adjusted to match the results of the analytical protocol in a prescribed sequence until changes in the model-of-composition between iterations fall below a prescribed tolerance.
a) Reconciliation by Constrained Optimization.
In the constrained optimization embodiment, we start with a model-of-composition whose reference molecular lump weight percents {wi*} exactly the results of the Micro-Hydrocarbon Analysis protocol. Next, we seek a new set of weight percents {wi} that are minimally different from those of the reference, yet satisfy the property balances described above. To find these weight percents, we minimize the Lagrangian L (see e.g Ref. [1]), defined by:
The first term in Equation (1) is the Shannon information entropy content of the model-of-composition's weight percents {wi} relative to that of the reference weight percents {wi*} (see e.g. Ref. [2]). The measured value of the property in the j-th balance is by. The density of property j in molecular lump i is aji. These property densities are either computed directly from each lump's molecular structure, or are correlated to measurements conducted on samples of known composition. λj is the Lagrangian multiplier of the j-th property balance constraint. NP is the total number of property balances considered in reconciliation. N is the number of molecular lumps in the model of composition. The Lagrangian L is minimized when the following stationary conditions are satisfied:
From ∂L/∂λj=0 we recover the property balance equations
We evaluate the functional derivative δL/δw using calculus of variations (see e.g. [3]). For the Lagrangian in Equation (3), the stationary solution is
Next, we substitute the stationary solution (4) into the property balance equations and eliminate the unknown weight percents {wi}:
We solve the nonlinear algebraic equations (4) on a digital computer for the Lagrangian multipliers {λk} using Newton's method. Once we have solved the equation system (4) for these Lagrangian multipliers, we substitute them into the stationary solution (3) and obtain the weight percents of the reconciled model-of-composition {Wi}.
b) Reconciliation by Successive Substitution
As in the constrained optimization reconciliation method described above, this embodiment of the reconciliation procedure also starts with model-of-composition whose reference molecular lump weight percents {wi*} exactly the results of the Micro-Hydrocarbon Analysis protocol. Adjustments to the weight percents {wi*} are done in sequence, i.e. the reconciled weight percents {wi} computed from the j-th property balance become the reference weight percents {Wi*} of the j+1-th property balance. Below we describe weight percent adjustment formulae for a scalar and distributed property targets, and the successive substitution reconciliation algorithm.
a) Scalar Property Targets
Scalar properties take a single number for the entire sample.
Simple Ratio Properties
A simple ratio property is linear in weight percents, its property density aji is nonzero for selected molecules, and equals zero for others. Examples of simple ratio properties include elemental composition. For simple ratio properties, we combine the property balance with a total mass balance to obtain:
Once we have adjusted (ratioed) the weight percents of molecules that possess the simple ratio property j, we adjust the weights of the molecules that do not possess this property:
Averaged Properties
Averaged properties are scalar properties whose property densities aji≠0 for all molecular lumps i=1, . . ., N. Examples of such averaged properties include API gravity, hydrogen content, octane number, and pour point. For averaged properties, the ratio method summarized in Equations 5 and 6 will not work. Instead, we have developed a factor φ that is a continuous function of the averaged property j whose target value equals bj. This factor adjusts upward the weights of molecules whose property density aji is less than that of the target bj, and it adjusts downward the weights of molecules whose property density aji is greater than the target value bj. The net result is to shift the distribution of weights {wi} toward a distribution that satisfies the property constraint equation
The continuous factor φ takes a cubic polynomial in the property value b:
φ(b)=A1b3+A2b2+A3b+A4 (7)
We determine the four constants A1 through A4 with the following constraints:
Conservation of total weight:
Averaged property constraint:
Smoothness at extreme values of the property j:
After we impose the constraints (8a-d) upon the factor φj defined in Equation 7, the factors and adjusted weights {wi} are computed as follows:
We avoid the occurrence of φ<0 by restricting the property target range (bmin,j, bmax,j). If the actual target bj is outside this range, we approach this target in multiple steps.
In the case of multiple average property targets, we may calculate separate weight factors φj for each target property j. However, we have achieved much greater effectiveness by using a single factor that includes the dependence of all averaged property targets. The factor adds all cubic polynomials together in Equation 7, with three additional parameters for each target. Constraints in Equation 8 are also used for each property. Final factors and weight adjustments are similar in form to Equations 9-12.
b) Distributed Property Targets
In general, a distributed property target occurs when the property to be matched varies with some independent variable. The distribution of weight distilled with boiling point temperature, i.e. the distillation curve, is the most frequently encountered distributed target. In the successive substitution method, we design a factor φ that effectively “redistills” the reference weight distribution {wi*} during each iteration of the reconciliation algorithm we describe below.
Let W(BP) represent the cumulative weight percent distilled off at boiling point BP. The measured target distribution is WT, and WD is calculated from the reference weight distribution {wi*} of the molecular lumps. Both of these cumulative weight distributions are monotonically increasing functions of the boiling point BP (see
where BPi is the boiling point of molecular lump i.
c) The Successive Substitution Reconciliation Algorithm
In
1. Denn, M. M. “Optimization by Variational Methods”, Chapter 1, McGraw-Hill, NYC, 1969.
2. Cover, T. M. and J. A. Thomas, “Elements of Information Theory”, p. 18. J. Wiley & Sons, 1991.
3. Davis, H. T., “Statistical Mechanics of Phases, Interphases and Thin Films”, Chapter 12, VCH Publishers, 1996.
This application claims the benefit of U.S. Provisional application 60/738,749 filed Nov. 22, 2005.
Number | Date | Country | |
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60738749 | Nov 2005 | US |