WO2005049663A2 - On-line measurement and control of polymer properties by raman spectroscopy - Google Patents
On-line measurement and control of polymer properties by raman spectroscopy Download PDFInfo
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- WO2005049663A2 WO2005049663A2 PCT/US2003/014565 US0314565W WO2005049663A2 WO 2005049663 A2 WO2005049663 A2 WO 2005049663A2 US 0314565 W US0314565 W US 0314565W WO 2005049663 A2 WO2005049663 A2 WO 2005049663A2
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N21/00—Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
- G01N21/62—Systems in which the material investigated is excited whereby it emits light or causes a change in wavelength of the incident light
- G01N21/63—Systems in which the material investigated is excited whereby it emits light or causes a change in wavelength of the incident light optically excited
- G01N21/65—Raman scattering
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J8/00—Chemical or physical processes in general, conducted in the presence of fluids and solid particles; Apparatus for such processes
- B01J8/18—Chemical or physical processes in general, conducted in the presence of fluids and solid particles; Apparatus for such processes with fluidised particles
- B01J8/1809—Controlling processes
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- C—CHEMISTRY; METALLURGY
- C08—ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
- C08F—MACROMOLECULAR COMPOUNDS OBTAINED BY REACTIONS ONLY INVOLVING CARBON-TO-CARBON UNSATURATED BONDS
- C08F10/00—Homopolymers and copolymers of unsaturated aliphatic hydrocarbons having only one carbon-to-carbon double bond
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J2208/00—Processes carried out in the presence of solid particles; Reactors therefor
- B01J2208/00796—Details of the reactor or of the particulate material
- B01J2208/00946—Features relating to the reactants or products
- B01J2208/00955—Sampling of the particulate material, the reactants or the products
- B01J2208/00973—Products
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J2219/00049—Controlling or regulating processes
- B01J2219/00191—Control algorithm
- B01J2219/00193—Sensing a parameter
- B01J2219/00195—Sensing a parameter of the reaction system
- B01J2219/00202—Sensing a parameter of the reaction system at the reactor outlet
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J2219/00049—Controlling or regulating processes
- B01J2219/00191—Control algorithm
- B01J2219/00211—Control algorithm comparing a sensed parameter with a pre-set value
- B01J2219/00218—Dynamically variable (in-line) parameter values
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J2219/00049—Controlling or regulating processes
- B01J2219/00191—Control algorithm
- B01J2219/00222—Control algorithm taking actions
- B01J2219/00227—Control algorithm taking actions modifying the operating conditions
- B01J2219/00229—Control algorithm taking actions modifying the operating conditions of the reaction system
- B01J2219/00231—Control algorithm taking actions modifying the operating conditions of the reaction system at the reactor inlet
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- C—CHEMISTRY; METALLURGY
- C08—ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
- C08F—MACROMOLECULAR COMPOUNDS OBTAINED BY REACTIONS ONLY INVOLVING CARBON-TO-CARBON UNSATURATED BONDS
- C08F210/00—Copolymers of unsaturated aliphatic hydrocarbons having only one carbon-to-carbon double bond
- C08F210/16—Copolymers of ethene with alpha-alkenes, e.g. EP rubbers
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- C—CHEMISTRY; METALLURGY
- C08—ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
- C08F—MACROMOLECULAR COMPOUNDS OBTAINED BY REACTIONS ONLY INVOLVING CARBON-TO-CARBON UNSATURATED BONDS
- C08F2400/00—Characteristics for processes of polymerization
- C08F2400/02—Control or adjustment of polymerization parameters
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N21/00—Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
- G01N21/62—Systems in which the material investigated is excited whereby it emits light or causes a change in wavelength of the incident light
- G01N21/63—Systems in which the material investigated is excited whereby it emits light or causes a change in wavelength of the incident light optically excited
- G01N21/65—Raman scattering
- G01N2021/653—Coherent methods [CARS]
- G01N2021/656—Raman microprobe
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2201/00—Features of devices classified in G01N21/00
- G01N2201/12—Circuits of general importance; Signal processing
- G01N2201/129—Using chemometrical methods
Definitions
- the present invention is directed generally to methods of measuring polymer properties on-line in a polymerization reactor system, and using those measured properties to control the polymerization reaction.
- the present invention provides methods of measuring properties of polyolefins such as melt index and density on-line, using Raman spectroscopy, and methods of controlling a reactor using real-time, on-line polymer property data provided by Raman spectroscopic measurements.
- Gas phase processes for the homopolymerization and copolymerization of monomers, especially olefin monomers, are well known in the art. Such processes can be conducted, for example, by introducing the gaseous monomer or monomers into a stirred and/or fluidized bed of resin particles and catalyst.
- the polymerization is conducted in a fluidized-bed reactor, wherein a bed of polymer particles is maintained in a fluidized state by means of an ascending gas stream including gaseous reaction monomer.
- the polymerization of olefins in a stirred-bed reactor differs from polymerization in a gas fluidized-bed reactor by the action of a mechanical stirrer within the reaction zone, which contributes to fluidization of the bed.
- the term "fluidized-bed” also includes stirred-bed processes and reactors.
- the start-up of a fluidized bed reactor generally uses a bed of pre-formed polymer particles.
- fresh polymer is generated by the catalytic polymerization of the monomer, and polymer product is withdrawn to maintain the bed at constant volume.
- An industrially favored process employs a fluidization grid to distribute the fluidizing gas to the bed, and also to act as a support for the bed when the supply of gas is cut off.
- the polymer produced is generally withdrawn from the reactor via one or more discharge conduits disposed in the lower portion of the reactor, near the fluidization grid.
- the fluidized bed includes a bed of growing polymer particles, polymer product particles and catalyst particles. This reaction mixture is maintained in a fluidized condition by the continuous upward flow from the base of the reactor of a fluidizing gas which includes recycle gas drawn from the top of the reactor, together with added make-up monomer.
- the fluidizing gas enters the bottom of the reactor and is passed, preferably through a fluidization grid, upwardly through the fluidized bed.
- the polymerization of olefins is an exothermic reaction, and it is therefore necessary to cool the bed to remove the heat of polymerization. In the absence of such cooling, the bed would increase in temperature until, for example, the catalyst became inactive or the polymer particles melted and began to fuse.
- a typical method for removing the heat of polymerization is by passing a cooling gas, such as the fluidizing gas, which is at a temperature lower than the desired polymerization temperature, through the fluidized-bed to conduct away the heat of polymerization.
- the recycle gas is removed from the reactor, cooled by passage through an external heat exchanger and then recycled to the bed.
- the temperature of the recycle gas can be adjusted in the heat exchanger to maintain the fluidized-bed at the desired polymerization temperature.
- the recycle gas generally includes one or more monomeric olefins, optionally together with, for example, an inert diluent gas or a gaseous chain transfer agent such as hydrogen.
- the recycle gas thus serves to supply monomer to the bed to fluidize the bed and to maintain the bed within a desired temperature range. Monomers consumed by conversion into polymer in the course of the polymerization reaction are normally replaced by adding make-up monomer to the recycle gas stream.
- the material exiting the reactor includes the polyolefin and a recycle stream containing unreacted monomer gases. Following polymerization, the polymer is recovered. If desired, the recycle stream can be compressed and cooled, and mixed with feed components, whereupon a gas phase and a liquid phase are then returned to the reactor.
- the polymerization process can use Ziegler-Natta and or metallocene catalysts.
- a variety of gas phase polymerization processes are known.
- the recycle stream can be cooled to a temperature below the dew point, resulting in condensing a portion of the recycle stream, as described in U.S. Patent Nos. 4,543,399 and 4,588,790.
- This intentional introduction of a liquid into a recycle stream or reactor during the process is referred to generally as a "condensed mode" operation.
- the properties of the polymer produced in the reactor are affected by a variety of operating parameters, such as temperatures, monomer feed rates, catalyst feed rates, and hydrogen gas concentration.
- operating parameters such as temperatures, monomer feed rates, catalyst feed rates, and hydrogen gas concentration.
- polymer exiting the reactor is sampled and laboratory measurements carried out to characterize the polymer. If it is discovered that one or more polymer properties are outside a desired range, polymerization conditions can be adjusted, and the polymer resampled. This periodic sampling, testing and adjusting, however, is undesirably slow, since sampling and laboratory testing of polymer properties such as melt index, molecular weight distribution and density is time-consuming.
- 5,999,255 discloses a method for measuring a physical property of a polymer sample, preferably nylon, by measuring a portion of a Raman spectrum of the polymer sample, determining a value of a preselected spectral feature from the Raman spectrum, and comparing the determined value to reference values. This method relies on identification and monitoring of preselected spectral features corresponding to identified functional groups, such as NH or methyl, of the polymer.
- the present invention provides a process for determining polymer properties in a polymerization reactor system.
- the process includes obtaining a regression model for determining a polymer property, the regression model including principal component loadings and principal component scores, acquiring a Raman spectrum of a polyolefin sample comprising polyolefin, calculating a new principal component score from at least a portion of the Raman spectrum and the principal component loadings, and calculating the polymer property by applying the new principal component score to the regression model.
- the present invention provides a process for controlling polymer properties in a polymerization reactor system.
- the process includes obtaining a regression model for determining a polymer property, the regression model including principal component loadings and principal component scores, acquiring a Raman spectrum of a polyolefin sample comprising polyolefin, calculating a new principal component score from at least a portion of the Raman spectrum and the principal component loadings, calculating the polymer property by applying the new principal component score to the regression model, and adjusting at least one polymerization parameter based on the calculated polymer property.
- the at least one polymerization parameter can be, for example, monomer feed rate, comonomer feed rate, catalyst feed rate, hydrogen gas feed rate, or reaction temperature.
- the regression model is constructed by obtaining a plurality of Raman spectra of polyolefin samples, calculating principal component loadings and principal component scores from the spectra using principal component analysis (PCA), and forming the regression model using the principal component scores such that the regression model correlates the polymer property to the principal component scores.
- PCA principal component analysis
- the regression model is a locally weighted regression model.
- the method includes: obtaining a first regression model for determining a first polymer property, the first regression model including first principal component loadings and first principal component scores; obtaining a second regression model for determining a second polymer property, the second regression model including second principal component loadings and second principal component scores; acquiring a Raman spectrum of a sample comprising polyolefin; calculating a new first principal component score from at least a portion of the Raman spectrum and the first principal component loadings; calculating a new second principal component score from at least a portion of the Raman spectrum and the second principal component loadings; calculating the first polymer property by applying the new first principal component score to the first regression model; and calculating the second polymer property by applying the new second principal component score to the second regression model.
- the sample includes polyolefin particles.
- the Raman spectrum is acquired by providing a sample of polyolefin particles and irradiating the sample and collecting scattered radiation during a sampling interval using a sampling probe, wherein there is relative motion between the sample and the sampling probe during at least a portion of the sampling interval. The relative motion serves to effectively increase the field of view of the sampling probe, providing more accurate data.
- the Raman spectrum is acquired from a probe inserted into the reactor or downstream from the reactor.
- the reactor is a gas phase polymerization reactor and more preferably is a fluidized bed reactor, e.g., a Unipol reactor or a gas phase, fluidized bed reactor having an optional cyclone.
- suitable polymer properties include, for example, density, melt flow rates such as melt index or flow index, molecular weight, molecular weight distribution, and various functions of such properties.
- Figure 1 is a block diagram of a gas-phase reactor.
- Figure 2 is a block diagram of a Raman analyzer according to the invention.
- Figure 3 illustrates one embodiment of a fiber optic Raman probe.
- Figure 4 illustrates one embodiment of a sample chamber.
- Figure 5 is a representative Raman spectrum of a granular linear low density polyethylene polymer sample.
- Figures 6a and 6b show predicted versus measured melt indices in low and high melt index ranges, respectively, according to Examples 1 and 2.
- Figure 7 shows predicted versus measured density according to
- FIG. 8a and 8b show predicted versus measured melt indices from online Raman analyses in metallocene- and Ziegler-Natta-catalyzed reactions, respectively, according to Examples 4-5.
- Figures 9a and 9b show predicted versus measured density from on-line Raman analyses in metallocene- and Ziegler-Natta-catalyzed reactions, respectively, according to Examples 6-7.
- Figure 10 shows predicted versus measured melt indices from on-line Raman analyses in a commercial-scale fluidized-bed reactor, over a period of about five weeks.
- Figure 11 shows predicted versus measured densities from on-line Raman analyses in a commercial-scale fluidized-bed reactor, over a period of about five weeks.
- the present invention provides a method of determining polyolefin polymer properties on-line, i.e., as the polyolefin is produced in a reactor system, without the need for external sampling and analysis.
- the method includes obtaining a regression model for determining a polymer property, the regression model including principal component loadings and principal component scores, acquiring a Raman spectrum of a polyolefin sample, calculating a new principal component score from at least a portion of the Raman spectrum and the principal component loadings, and calculating the polymer property by applying the new principal component score to the regression model.
- the method is used to determine polymer properties on-line in a fluidized-bed reactor system.
- Fluidized-bed reactors are well-known in the art; a particular, non-limiting example of a fluidized bed reactor is described herein, for illustrative purposes only. Those skilled in the art will recognize that numerous modifications and enhancements can be made, as desired, to the fluidized-bed reactor.
- Fluidized-Bed Reactor
- FIG. 1 illustrates one example of a gas phase polymerization reactor system which comprises a gas-phase ' fluidized bed reactor 20 having a reactor body 22, which is generally an upright cylinder having a fluidization grid 24 located in its lower regions.
- the reactor body 22 encloses a fluidized bed zone 26 and a velocity reduction zone 28 which is generally of increased diameter compared to the diameter of the fluidized bed zone 26 of the reactor body 22.
- the gaseous reaction mixture leaving the top of the reactor body 22, termed the "recycle gas stream,” contains principally unreacted monomer, unreacted hydrogen gas, inert condensable gases such as isopentane, and inert non-condensable gases such as nitrogen.
- the recycle gas stream is transferred via line 30 to compressor 32, and from compressor 32 to heat exchanger 34.
- An optional cyclone separator 36 may be used as shown, preferably upstream of compressor 32, to remove fines, if desired.
- An optional gas analyzer 38 can be used if desired, to sample the recycle gas stream to determine concentrations of various components.
- the gas analyzer is a gas phase chromatograph (GPC), or a spectrograph such as a near-infrared spectrometer or a fourier transform near-infrared spectrometer (FT-NIR).
- An additional heat exchanger (not shown) may also be used if desired, preferably upstream of compressor 32.
- the cooled recycle gas stream exits the heat exchanger 34 via line 40.
- the cooled recycle gas stream can be gaseous, or can be a mixture of gaseous and liquid phases.
- Figure 1 shows an optional configuration wherein at least a portion of the recycle gas stream is cooled to a temperature at or below the temperature where liquid condensate begins to form (the dew point). All or a portion of the resultant gas liquid mixture is transferred via line 40 to a separator 42, where all or a portion of the liquid is removed. All or a portion of the gas stream, which may contain some liquid, is transferred via line 44 to a point below the fluidization grid 24 in the lower region of the reactor. An amount of upwardly flowing gas, sufficient to maintain the bed in a fluidized condition, is provided in this way.
- An optional compressor 46 may be provided to ensure that a sufficient velocity is imparted to the gases flowing through line 44 into the bottom of the reactor.
- the gas stream entering the bottom of the reactor may contain condensed liquid, if desired.
- All or a portion of the liquid phase separated from the recycle stream in separator 42 is transferred via line 48 to a manifold 50 located at or near the top of the reactor.
- a pump 52 may be provided in line 48 to facilitate the transfer of liquid to manifold 50.
- the liquid entering manifold 50 flows downward into manifold 54 through a plurality of conduits 56 which have good heat exchange properties and which are in heat exchange contact with the wall of the reactor.
- the passage of liquid through the conduits 56 cools the interior wall of the reactor and warms the liquid to a greater or lesser extent, depending upon the temperature differential and the duration and extent of heat exchange contact.
- the heated fluid (gas and/or liquid) is passed from manifold 54 via line 58 to combine with gases leaving the separator 42 via line 44, prior to entry into the reactor in the region below the fluidization grid 24.
- make-up monomer can be introduced into the reactor in either liquid or gaseous form via line 60.
- Gas and/or liquid collected in manifold 54 may also be transferred directly into the reactor (not shown) in the region below the fluidization grid.
- Product polymer particles can be removed from the reactor via line 62 in the conventional way, as for example by the method and apparatus described in U.S. Pat. No. 4,621,952. Although only one line 62 is shown in the Figure, typical reactors can include more than one line 62.
- Catalyst is continuously or intermittently injected into the reactor using a catalyst feeder (not shown) such as the device disclosed in U.S. Pat. No. 3,779,712. The catalyst is preferably fed into the reactor at a point 20 to 40 percent of the reactor diameter away from the reactor wall and at a height of about 5 to about 30 percent of the height of the bed.
- the catalyst can be any catalyst suitable for use in a fluidized bed reactor and capable of polymerizing ethylene, such as one or more metallocene catalysts, one or more Ziegler-Natta catalysts, bimetallic catalysts, or mixtures of catalysts.
- a gas which is inert to the catalyst such as nitrogen or argon, is preferably used to carry catalyst into the bed.
- Cold condensed liquid from either separator 42 or from manifold 54 may also be used to transport catalyst into the bed.
- the fluidized bed reactor is operated to form at least one polyolefin homopolymer or copolymer.
- Suitable polyolefins include, but are not limited to, polyethylene, polypropylene, polyisobutylene, and homopolymers and copolymers thereof.
- the at least one polyolefin includes polyethylene homopolymer and/or copolymer.
- Low density polyethylene (“LDPE”) can be prepared at high pressure using free radical initiators, or in gas phase processes using Ziegler-Natta or vanadium catalysts, and typically has a density in the range of 0.916-0.940 g/cm .
- LDPE is also known as "branched” or “heterogeneously branched” polyethylene because of the relatively large number of long chain branches extending from the main polymer backbone.
- Polyethylene in the same density range i.e., 0.916 to 0.940 g/cm 3 , which is linear and does not contain long chain branching is also known; this "linear low density polyethylene” (“LLDPE”) can be produced with conventional Ziegler-Natta catalysts or with metallocene catalysts.
- LLDPE linear low density polyethylene
- Relatively higher density LDPE typically in the range of 0.928 to 0.940g/cm 3 , is sometimes referred to as medium density polyethylene (“MDPE”).
- MDPE medium density polyethylene
- Polyethylenes having still greater density are the high density polyethylenes (“HDPEs”), i.e., polyethylenes having densities greater than 0.940 g/cm 3 , and are generally prepared with Ziegler-Natta catalysts.
- HDPEs high density polyethylenes
- VLDPE Very low density polyethylene
- Suitable comonomers include ⁇ -olefins, such as C 3 -C 20 ⁇ -olefins or C 3 -C 12 ⁇ -olefins.
- the ⁇ -olefin comonomer can be linear or branched, and two or more comonomers can be used, if desired.
- suitable comonomers include linear C 3 -C 1 ⁇ -olefins, and ⁇ -olefins having one or more C ⁇ -C 3 alkyl branches, or an aryl group. Specific examples include propylene; 3 -methyl- 1-butene;
- comonomers include propylene, 1-butene, 1-pentene, 4-methyl-l- pentene, 1-hexene, 1-octene and styrene.
- Non-conjugated dienes useful as co- monomers preferably are straight chain, hydrocarbon diolefins or cycloalkenyl- substituted alkenes, having 6 to 15 carbon atoms.
- Suitable non-conjugated dienes include, for example: (a) straight chain acyclic dienes, such as 1,4-hexadiene and 1 ,6-octadiene; (b) branched chain acyclic dienes, such as 5-methyl- 1,4-hexadiene; 3,7-dimethyl-l,6-octadiene; and 3,7-dimethyl-l,7-octadiene; (c) single ring alicyclic dienes, such as 1 ,4-cyclohexadiene; 1,5-cyclo-octadiene and 1,7- cyclododecadiene; (d) multi-ring alicyclic fused and bridged ring dienes, such as tetrahydroindene; norbornadiene; methyl-tetrahydroindene; dicyclopentadiene (DCPD); bicyclo-(2.2.1)-hepta-2,5-diene; alkenyl, al
- the preferred dienes are dicyclopentadiene, 1,4-hexadiene, 5-methylene-2-norbornene, 5-ethylidene-2- norbornene, and tetracyclo-( ⁇ -l l,12)-5,8-dodecene.
- Particularly preferred diolefins are 5-ethylidene-2-norbornene (ENB), 1,4-hexadiene, dicyclopentadiene (DCPD), norbornadiene, and 5-vinyl-2-norbornene (VNB).
- the amount of comonomer used will depend upon the desired density of the polyolefin and the specific comonomers selected. One skilled in the art can readily determine the appropriate comonomer content appropriate to produce a polyolefin having a desired density.
- Raman spectroscopy is a well-known analytical tool for molecular characterization, identification, and quantification.
- Raman spectroscopy makes use of inelastically scattered radiation from a non-resonant, non-ionizing radiation source, typically a visible or near-infrared radiation source such as a laser, to obtain information about molecular vibrational-rotational states.
- a non-resonant, non-ionizing radiation source typically a visible or near-infrared radiation source such as a laser
- non- ionizing, non-resonant radiation is scattered elastically and isotropically (Raleigh scattering) from a scattering center, such as a molecule.
- Raman spectra are typically shown as plots of intensity (arbitrary units) versus "Raman shift", where the Raman shift is the difference in energy or wavelength between the excitation radiation and the scattered radiation.
- the Raman shift is typically reported in units of wavenumbers (cm "1 ), i.e., the reciprocal of the wavelength shift in centimeters.
- the spectral region acquired can be less than all of the 100 cm “1 to 4000 cm “1 region.
- the majority of Raman scattering intensity will be present in a region from about 500 cm “1 to about 3500 cm “1 or from 1000 cm “1 to 3000 cm “1 .
- the region acquired can also include a plurality of sub-regions that need not be contiguous.
- Raman scattering intensity data is useful in determining properties of polyolefin particles without the need to identify, select, or resolve particular spectral features. Thus, it is not necessary to identify a particular spectral feature as being due to a particular mode of a particular moiety of the polyolefin, nor is it necessary to selectively monitor Raman scattering corresponding to a selected spectral feature.
- the Raman spectral data acquired and used includes a plurality of frequency or wavelength shift, scattering intensity (x, y) measurements over relatively broad spectral regions, including regions conventionally identified as spectral bands and regions conventionally identified as interband, or unresolved regions.
- the frequency spacing of acquired data can be readily determined by one skilled in the art, based on considerations of machine resolution and capacity, acquisition time, data analysis time, and information density. Similarly, the amount of signal averaging used is readily determined by one skilled in the art based on machine and process efficiencies and limitations.
- the spectral region measured can include Stokes scattering (i.e., radiation scattered at frequencies lower than the excitation frequency), anti-Stokes scattering (i.e., radiation scattered at frequencies higher than the excitation frequency), or both.
- polarization information embedded in the Raman scattering signal can also be used, and one skilled in the art readily understands how to acquire Raman polarization information.
- any Raman polarization is essentially randomized as a result of interactions with the fiber optic conduit used to convey the signal to the signal analyzer, as described below.
- the instrumentation used to collect and process Raman data includes a Raman subsystem 100, a sample subsystem 200, and a data subsystem 300.
- the sample subsystem 200 is in communication with reactor 20 via polymer output line 62 (see also Figure 1).
- polymer output line 62 see also Figure 1.
- Figure 2 illustrates the case wherein the sampling is extractive, as opposed to the case wherein the sampling is in situ, as described in more detail below.
- the Raman probe 204 may be inserted directly into reactor body 22. Reactor body 22 may thus act as sample subsystem 200. It will be recognized by one of skill in the art in possession of the present disclosure that Raman probe 204 may be used anywhere in process where granular resin could be collected and analyzed by a Raman probe or anywhere in the process where granular resin can move relative to a Raman probe, e.g., in the cycle gas piping (e.g., line 30 in Fig. 1), in the product discharge system downstream of the exiting point of product (e.g., from 22 into line(s) 62 in Fig.
- Raman probe 204 is inserted into fluidized bed zone 26, more preferably in the lower half of zone 26 but above grid 24. '
- the Raman subsystem includes a Raman spectrometer, the principal components of which are an excitation source 102, a monochromator 104, and a detector 106.
- Raman spectrometers are well-known analytical instruments, and thus only a brief description is provided herein.
- a Raman spectrometer includes an excitation source 102 which delivers excitation radiation to the sample subsystem 200. Scattered radiation is collected within the sample subsystem 200 (described below), filtered of Raleigh scattered light, and dispersed via monochromator 104. The dispersed Raman scattered light is then imaged onto a detector 106 and subsequently processed in data subsystem 300, as further described below.
- the excitation source and frequency can be readily determined based on considerations well-known in the art.
- the excitation source 102 is a visible or near infrared laser, such as a frequency-doubled Nd:YAG laser (532 nm), a helium-neon laser (633 nm), or a solid-state diode laser (such as 785 ran).
- the laser can be pulsed or continuous wave (CW), polarized as desired or randomly polarized, and preferably single-mode.
- Typical excitation lasers will have 100 to 400 mW power (CW), although lower or higher power can be used as desired.
- Light sources other than lasers can be used, and wavelengths and laser types and parameters other than those listed above can also be used.
- the excitation radiation can be delivered to the sample subsystem 200, and the scattered radiation collected from the sample subsystem, by any convenient means known in the art, such as conventional beam manipulation optics, or fiber optic cables.
- the scattered radiation is collected and dispersed by any convenient means known in the art, such as a fiber optic probe as described below.
- the collected scattered radiation is filtered to remove Raleigh scattering and optionally filtered to remove fluorescence, then frequency (wavelength) dispersed using a suitable dispersive element, such as a blazed grating or a holographic grating, or interferometrically (e.g., using Fourier transforms).
- a suitable dispersive element such as a blazed grating or a holographic grating, or interferometrically (e.g., using Fourier transforms).
- the grating can be fixed or scanning, depending upon the type of detector used.
- the monochromator 104 can be any such dispersive element, along with associated filters and beam manipulation optics. Detector
- the dispersed Raman scattering is imaged onto a detector 106.
- detector The choice of detector is easily made by one skilled in the art, taking into account various factors such as resolution, sensitivity to the appropriate frequency range, response time, etc.
- Typical detectors include array detectors generally used with fixed- dispersive monochromators, such as diode arrays or charge coupled devices (CCDs), or single element detectors generally used with scanning-dispersive monochromators, such as lead sulfide detectors and indium-gallium-arsenide detectors.
- the detector is calibrated such that the frequency (wavelength) corresponding to each detector element is known.
- the detector response is delivered to the data subsystem 300 which generates a set of frequency shift, intensity (x,y) data points which constitute the Raman spectrum.
- the sample subsystem 200 couples the Raman subsystem 100 to the polymerization process.
- the sample subsystem 200 delivers the excitation radiation from the excitation source 102 to the polymer sample, collects the scattered radiation, and delivers the scattered radiation to the monochromator 104.
- the excitation radiation can be delivered to and collected from the polymer sample by any convenient means, such as using conventional optics or fiber optic cables.
- the sample subsystem includes a probe 204 and a sample chamber 202.
- Figure 3 shows a block diagram of one embodiment of a fiber optic probe.
- the probe includes a fiber optic bundle 206 including one or more fiber optic cables 208 carrying the excitation radiation from the excitation source toward the sample, and one or more fiber optic cables 210 carrying the collected scattered radiation from the sample.
- Fiber optic cables 208 are in optical communication with the excitation source (102 in Figure 2), and fiber optic cables 210 are in optical communication with the monochromator (104 in Figure 2).
- the excitation and scattered radiation can be manipulated using well-known techniques.
- the particular optical setup shown in Figure 3 is merely exemplary.
- Excitation radiation 212 is directed via optics 214 to a holographic grating 216 and spatial filter 218 to remove silica Raman due to the fiber optic cable, then directed via mirror 220 and beam combiner 222 to sampling optics 224 and sample chamber 202. Scattered radiation is collected via sampling optics 224 and directed through beam combiner 222, a notch filter 226 to remove the Raleigh scattered radiation, and into fiber optic cables 210.
- the sample in the sample chamber includes a plurality of polymer particles (granules), and represents the polymer product as discharged from the reactor.
- the sample it is not necessary that the sample be free of liquid- phase components, such as residual solvent or other liquid hydrocarbons that may be present in the polymer in the discharge line of a fluidized-bed reactor.
- Raman probes such as described herein are imaging, in that they have a focused field of view.
- An imaging probe is the most efficient optical configuration, and because the Raman signal is weak the imaging probe collects as much scattered light as possible.
- a disadvantage of an imaging probe is that the probe "sees" only a very small amount of the sample at any one time. For a typical fluidized-bed process, a fixed imaging probe has a field of view corresponding to only 1 or 2 polymer granules. Thus, the data collected in a static mode may not be representative of the bulk material.
- the disadvantage of a limited field of view is overcome by providing relative motion between the sample and the Raman probe, so that the probe collects scattering from many polymer granules over the course of the sampling interval.
- the probe can be moved through the sample during at least a portion of the sampling interval or, equivalently, the sample or sample chamber can be moved relative to a fixed probe during at least a portion of the sampling interval, or both can be moved.
- it is convenient to keep the sample chamber stationary and move the Raman probe into and out of the sample chamber during the sampling interval by linearly translating the probe using a linear actuator.
- the polymerization reactor system be a gas phase polymerization reactor system.
- the probe may be purged of collected polymer product to prevent the field of view from getting coated. This may be accomplished, for instance, by the use of a purge with N 2 , H 2 , ethylene, isopentane, hexane, mineral oil, n-butane and the like. In an even more preferred embodiment, there is a cycling between periods of data collection and probe purge in order to obtain optimal readings.
- the probe purge/data collection cycle times may be varied, and the depth of the probe insertion may also be varied.
- One advantage of inserting the probe directly into reactor body 22 is earlier indication of polymer properties and also problems with reactor operability, such as onset of sheeting or fouling which may cause the probe tip to plug.
- each reactor 20 (only one reactor shown) has two dump valves A and B that alternate to remove product from the reactor.
- the product is pneumatically conveyed through product discharge pipe 62 with 90 psi (0.6 MPa) nitrogen at a speed of about 60 miles per hour (0.4 m/s). At this speed the slug of product dumped from a reactor will only be present at any one point in the pipe for a few seconds.
- the Raman signal for 60-120 seconds to improve the signal- to-noise ratio.
- a small amount of product (about 800 grams) is trapped and held in a sample chamber 202 as the slug passes through the product discharge pipe 62.
- the sample chamber 202 is attached to the product discharge pipe 62 by a 1 inch (25 mm) diameter pipe 62b and a pneumatically actuated valve C or D.
- the operation of the valves C and D is controlled by the Raman analyzer, but could also be controlled by an auxiliary system.
- the Raman analyzer waits for a signal from the reactor telling it that the dump valve A or B has opened.
- the Raman analyzer then opens valve C or D connecting the sample chamber 202 to the product discharge pipe 62, and waits for a time predetermined to be sufficient to have allowed the slug of product to have passed by the sample capture point.
- the Raman analyzer next closes the sample capture valve C or D, trapping the captured sample of product in the sample chamber 202.
- the Raman analyzer probe 204 includes a probe head 230 enclosing the filtering and optical (not electronic) signal processing elements, and a sample interface 232, which is an 8" long by 0.5" diameter (20 cm x 1.3 cm) tube. Tube 232 is inserted through the end of the sample chamber opposite to where the sample enters, so that it comes in contact with the sample.
- a pneumatic linear actuator 234 is attached to the probe 204 to slowly draw the probe out of the sample chamber and then reinsert it during a sample collection interval. This probe movement causes sample to flow across the front of the probe, providing a continually changing sample for measurement.
- the reactor 20 dumps on a 3-6 minute cycle (grade dependent), alternating between 2 lines 62 controlled by valves A and B. Sample is collected from only one of the lines. The sample system operates by waiting for a Sample Ready signal from the reactor telling the Raman analyzer that a sample is being dumped. The Sample Ready signal is in the form of a digital input to the Raman analyzer.
- the analyzer When the analyzer receives the Sample Ready signal, there is a sequence of tasks it performs prior to setting up the valves for the Capture Sample operation, which are: [0083] Check to determine if the Sample Ready is for the next stream. In the Raman control software, there is a stream sequence list that the operator sets to tell the analyzer which reactor(s) to sample and measure. Typically, this would be 1,2,1,2, etc., for a two reactor system, but under some circumstances such as a grade transition on reactor 1, the operator might want to sample, for example, 1,1,1,2,1,1,2, etc. Thus, the analyzer checks to make sure the dump indicator it receives is consistent with the current stream sequence. If not, the analyzer ignores the signal.
- valve states are shown in the table below for a sequence sampling through the A valve of product discharge line 62, with state “C” being closed, and state “O” being open.
- Sample Capture is accomplished by opening the sample chamber valves C and D.
- an open valve C permits the sample to enter sample chamber 202
- an open valve D serves as a vent.
- a portion of the discharged polymer product in 90 psig nitrogen being transported at about 60 miles per hour packs into the sample chamber 202 attached to a bend in the product discharge line 62.
- the probe is attached to linear actuator so that it can be moved in and out of the sample chamber.
- the probe In the Waiting for Sample state (5), the probe is fully inserted into the sample chamber so that the shaft of the probe is immersed in sample after the chamber is filled.
- the Measure Spectrum valve state (2) not only closes valves C and D, but also actuates both three-way valves controlling the linear actuator so that the probe is slowly extracted from the sample chamber while data is being collected.
- the sample in the sample chamber is ejected back into the sample transport line by opening valves C and E.
- the data subsystem includes an analyzer 302, which receives the response signal of the detector 106.
- the analyzer can be, for example, a computer capable of storing and processing the Raman data. Other functions of the analyzer can include, for example, developing the regression model and carrying out PCA/LWR analysis, as described below.
- the data subsystem controls the motion of the sampling probe. In another embodiment described above, the data subsystem controls valves for filling and emptying the sample chamber. In another embodiment, the data subsystem compares the calculated value of one or more polymer properties to a target value, and adjusts one or more reactor parameters in response to the deviation between calculated and target values. Reactor control is further described below.
- the Raman spectrum includes information directly or indirectly related to various properties of the polyolefin sample.
- sample components are identified by the presence of unique spectral signatures, such as particular bands recognized as being due to particular vibrational modes of a molecule.
- Quantitative information such as concentration can then be obtained about a sample component by, for example, integrating the area under a particular peak and comparing the area to a calibration sample, by monitoring scattered intensity at a particular peak as a function of time, etc.
- the present inventors have surprisingly found that polymer properties can be determined from Raman spectra without the need to identify or select particular spectral features, by using a multivariate model to correlate polymer properties with Raman scattering data.
- the model uses large, contiguous regions of the spectrum, rather than discrete spectral bands, thereby capturing large amounts of information density unavailable and unrecognized in conventional analysis. Further, the spectral data are correlated to polymer properties such as melt flow rates (defined below), densities, molecular weight distributions, etc., that are not readily apparent from optical spectra.
- the data analysis described below is used to build and apply a predictive model for at least one property of the polyolefin particles selected from melt flow rate, density, molecular weight, molecular weight distribution, and functions thereof.
- melt flow rate indicates any of the . various quantities defined according to ASTM D-1238, including I 2 . ⁇ 6 , the melt flow rate of the polymer measured according to ASTM D-1238, condition E (2.16 kg load, 190 °C), commonly termed the “melt index", and I 21 . 6 , the melt flow rate of the polymer measured according to ASTM D-1238, condition F (21.6 kg load, 190 °C), commonly termed the "flow index.”
- Other melt flow rates can be specified at different temperatures or different loads.
- the ratio of two melt flow rates is the "Melt Flow Ratio" or MFR, and is most commonly the ratio of I21.6/I2.16.
- MFR can be used generally to indicate a ratio of melt flow rates measured at a higher load (numerator) to a lower load (denominator).
- molecular weight indicates any of the moments of the molecular weight distribution, such as the number average, weight average, or Z- average molecular weights, and “molecular weight distribution” indicates the ratio of two such molecular weights.
- molecular weights M can be computed from the expression:
- Nj is the number of molecules having a molecular weight M;.
- M is the number average molecular weight Mn.
- M is the weight average molecular weight Mw.
- M is the Z-average molecular weight Mz.
- Methods of the invention include obtaining a regression model for determining a polymer property, the regression model including principal component loadings and principal component scores; acquiring a Raman spectrum of a polyolefin sample; calculating a new principal component score from at least a portion of the Raman spectrum and the principal component loadings; and calculating the polymer property by applying the new principal component score to the regression model.
- the regression model is preferable a locally weighted regression (LWR) model, using principal component analysis (PCA) eigenvectors.
- PCA is a well- known analytical method, and is described, for example, in PirouetteTM Multivariate Data Analysis for Windows software manual, Infometrix, Inc, Woodinville, WA (1985-2000), PLS ToolboxTM software manual, Eigenvector Research, Inc., Manson, WA (1998), and references cited therein.
- LWR is described, for example, in Naes and Isaksson, Analytical Chemistry, 62, 664-673 (1990), Sekulic et al., Analytical Chemistry, 65, 835A-845A (1993), and references cited therein.
- Principal Components Analysis is a mathematical method which forms linear combinations of raw variables to construct a set of mutually orthogonal eigenvectors (principal component loadings).
- PCA can calculate the eigenvectors in order of decreasing variance.
- the analysis computes a number of eigenvectors equal to the number of original variables, in practice, the first few eigenvectors capture a large amount of the sample variance. Thus, only a relatively small number of eigenvectors is needed to adequately capture the variance, and a large number of eigenvectors capturing minimal variance can be disregarded, if desired.
- the data are expressed in an m (row) by n (column) matrix X, with each sample being a row and each variable a column optionally mean centered, autoscaled, scaled by another function or not scaled.
- the eigenvectors L are eigenvectors of the covariance matrix, with the corresponding eigenvalues ⁇ ; indicating the relative amount of covariance captured by each eigenvector.
- the linear combination can be truncated after the sum of the remaining eigenvalues reaches an acceptably small value.
- a model can be constructed correlating the Raman scattering intensity •with a polymer property in PCA space using various linear or nonlinear mathematical models, such as principal components regression (PCR), partial least squares (PLS), projection pursuit regression (PPR), alternating conditional expectations (ACE), multivariate adaptive regression splines (MARS), and neural networks (NN), to name a few.
- the model is a locally weighted regression model.
- Locally Weighted Regression assumes that a smooth non-linear function can be approximated by a linear or relatively simple non-linear (such as quadratic) function, with only the closest data points being used in the regression. ⁇ The q closest points are used and are weighted by proximity, and the regression model is applied to the locally weighted values.
- Raman spectra are acquired, and the polymer properties of the sample are measured in the laboratory. The properties measured include those that the model will predict, such as density, melt flow rates, molecular weights, molecular weight distributions, and functions thereof.
- the data set including the measured polymer properties the samples and the Raman spectral data for the samples is decomposed into PCA space to obtain a calibration data set. No particular number of calibration samples is required. One skilled in the art can determine the appropriate number of
- the LWR model can be validated using methods known in the art. It is convenient to divide the calibration samples into two sets: a calibration data set, and a validation data set. The calibration data set is used to develop the model, and to predict the appropriate polymer property for the samples in the validation data set, using the validation data set Raman spectra. Since the chosen polymer property for the validation data set samples is both calculated and measured, the effectiveness of the model can be evaluated by comparing the calculated and measured values.
- the validated model can then be applied to sample spectra to predict the desired polymer property or properties.
- a single model can be used to predict two or more polymer properties. Preferably, separate models are developed for each polymer property.
- the present invention includes: obtaining a first regression model for determining a first polymer property, the first regression model including first principal component loadings and first principal component scores; obtaining a second regression model for determining a second polymer property, the second regression model including second principal component loadings and second principal component scores; acquiring a Raman spectrum of a sample comprising polyolefin; calculating a new first principal component score from at least a portion of the Raman spectrum and the first principal component loadings; calculating a new second principal component score from at least a portion of the Raman spectrum and the second principal component loadings; calculating the first polymer property by applying the new first principal component score to the first regression model; and calculating the second polymer property by applying the new second principal component score to the second regression model.
- more than two polymer properties can be determined by including third or more regression models.
- multiple polymer properties can be determined essentially simultaneously by using the same Raman spectrum and applying several regression models to the spectral data.
- two regression models are used, and both a melt flow rate (such as melt index I 2 . ⁇ 6 or flow index I 2 ⁇ . 6 ) and density are determined.
- the calculated polymer property is compared to a target polymer property, and at least one reactor parameter is adjusted based on the deviation between the calculated and target polymer property.
- the at least one reactor parameter can include the amounts of monomer, comonomer, catalyst and cocatalyst, the operating temperature of the reactor, the ratio of comonomer(s) to monomer, the ratio of hydrogen to monomer or comonomer, and other parameters that affect the chosen polymer property.
- a reactor parameter can be adjusted to increase density, such as, for example, reducing the comonomer feed rate and/or increasing the monomer feed rate.
- hydrogen can serve as a chain transfer agent. In this way, the molecular weight of the polymer product can be controlled.
- varying the hydrogen concentration in olefin polymerization reactors can also vary the polymer melt flow rate, such as the melt index I 2 . 16 (MI).
- MI melt index
- EXCEEDTM 350 is a gas-phase metallocene produced LLDPE ethylene/hexene copolymer with a Melt Index (I 2 . ⁇ 6 ) of 1.0 g/ 10 min, and a density of 0.918 g/cm 3 , available from ExxonMobil Chemical Co., Houston, TX.
- the EXCEEDTM 350 resin is now marketed as EXCEEDTM 3518.
- EXCEEDTM 357 is a gas-phase metallocene produced LLDPE ethylene/hexene copolymer with a Melt Index (I 2 . ⁇ 6 ) of 3.4 g/ 10 min, and a density of 0.917 g/cm 3 , available from ExxonMobil Chemical Co., Houston, TX.
- the EXCEEDTM 357 resin is now marketed as EXCEEDTM 3518.
- ExxonMobil LL-1002 is a gas-phase Ziegler-Natta produced LLDPE ethylene/butene copolymer resin having a Melt Index (I 2 . ⁇ 6 ) of 2.0 g/ 10 min, and a density of 0.918 g/cm 3 , available from ExxonMobil Chemical Co., Houston, TX.
- ExxonMobil LL-1107 is a gas-phase Ziegler-Natta produced LLDPE ethylene/butene copolymer resin having a Melt Index (I . ⁇ 6 ) of 0.8 g/ 10 min, and a density of 0.922 g/cm 3 , available from ExxonMobil Chemical Co., Houston, TX.
- ExxonMobil LL-6100 is a gas-phase Ziegler-Natta produced LLDPE ethylene/butene copolymer resin having a Melt Index (I 2 . ⁇ 6 ) of 20 g/10 min, and a density of 0.925 g/cm 3 , available from ExxonMobil Chemical Co., Houston, TX.
- ExxonMobil LL-6101 is a gas-phase Ziegler-Natta produced LLDPE ethylene/butene copolymer resin having a Melt Index (I 2 . ⁇ 6 ) of 20 g/10 min, and a density of 0.925 g/cm 3 , available from ExxonMobil Chemical Co., Houston, TX.
- ExxonMobil LL-6201 is a gas-phase Ziegler-Natta produced LLDPE ethylene/butene copolymer resin having a Melt Index (I 2 . ⁇ 6 ) of 50 g/10 min, and a density of 0.926 g/cm 3 , available from ExxonMobil Chemical Co., Houston, TX.
- Examples 1-3 were used to show the feasibility of embodiments of the invention. In Examples 1-3, measurements were made in the laboratory, simulating the measurements that would be made on-line in a polymerization reactor.
- the Raman system used for Examples 1-3 was a Kaiser Optical Holoprobe Process Raman Analyzer, available from Kaiser Optical Systems, Inc., Ann Arbor, Michigan. The Raman system used a 125 mW diode laser operating at 785 nm, and was equipped with a probe with 2.5 (6.3 cm) inch imaging optics fiber- optically coupled to the instrument, a holographic notch filter, holographic dispersion grating, cooled CCD detector (-40 °C), and computer for analyzer control and data analysis.
- Figure 6A depicts the data from Tables 1 and 2 graphically.
- the line in the Figure is the model prediction.
- the calculated R 2 value was 0.99 for the calibration set, with a standard error of 0.0155, and 0.92 for the validation set, with a standard error of 0.059.
- Example 2 An analysis was carried out as in Example 1, using higher melt index samples. Thirty-four polymer samples were evaluated. These samples were used as calibration samples for model development, but a validation subset was not used. Each sample was a metallocene-catalyzed LLDPE resin, with butene comonomer, in a melt index range of from about 4 to about 60 g/10 min. Raman spectra and laboratory melt index measurements were collected as described above. [0138] The lab values of melt index and the Raman spectra of the calibration data set were used to create a locally-weighted regression model for high range melt index, using principal component loadings and principal component scores.
- Table 3 High MI Calibration MI (Lab) MI (Model) ⁇ MI (a) MI (Lab) MI (Model) ⁇ MI (a) (dg/min) (dg/min) (dg/min) (dg/min) (dg/min) (dg/min) 4.341 4.513 0.172 30.68 29.118 -1.562 4.341 4.467 0.126 32.93 32.112 -0.818 8.613 8.433 -0.18 32.93 32.459 -0.471 8.613 8.314 -0.299 33.68 34.658 0.978 10.499 9.978 -0.521 33.68 34.233 0.553 10.499 10.768 0.269 36.6 37.216 0.616 12.547 13.013 0.466 36.6 36.989 0.389 12.547 12.971 0.424 45.15 44.4
- Figure 6B depicts the data from Table 3 graphically.
- the line in the Figure is the model prediction.
- the calculated R 2 value was 0.99, with a standard error of 0.91.
- Example 3 Density Model
- Example 1 An analysis was carried out as in Example 1, using density rather than melt index as the predicted property. A subset of 22 of the polymer samples used in Example 1 were evaluated. These samples were used as calibration samples for model development, but a validation subset was not used. Each sample was a metallocene-catalyzed LLDPE resin, with hexene comonomer. Raman spectra and laboratory density measurements were collected as described above. [0141] The lab values of density and the Raman spectra of the calibration data set were used to create a locally-weighted regression model for density, using principal component loadings and principal component scores.
- Figure 7 depicts the data graphically.
- the line in the Figure is the model prediction.
- the calculated R 2 value was 0.95, with a standard error of 0.00057. Examples 4-5
- Examples 4-5 demonstrate the effectiveness of the inventive methods online in a polymerization reaction system, for melt index determination.
- the Raman system used for Examples 4-5 was as described for Examples 1-3, except that the laser was a 200 mW mode-stabilized diode laser operating at 785 nm. Polymer samples from either of two gas-phase fluidized-bed reactors were taken using the sampling system described above.
- Table 5A MI Calibration, Reactor 1 I (Lab) MI (Model) MI (Lab) MI (Model) MI (Lab) MI (Model) MI (Lab) MI (Model) (dg/min) (dg/min) (dg/min) (dg/min) (dg/min) 4.997 5.013 3.506 3.440 0.967 0.973 4.413 4.390 3.554 3.401 0.952 0.961 4.559 4.410 3.554 3.474 0.956 0.977 3.511 3.633 3.541 3.540 0.969 0.940 3.481 3.521 3.576 3.713 0.973 0.994 3.315 3.391 3.576 3.679 0.946 0.980 3.301 3.286 3.630 3.664 0.972 0.960 3.369 3.211 3.630 3.664 1.135 1.083 3.460 3.607 3.626 3.563 1.188 1.209 3.391 3.481 3.618 3.652 1.182 1.231 3.380 3.301 3.346 3.257 1.
- melt index of each validation sample was then calculated.
- the measured and predicted melt indexes are shown in Table 6. Acquisition of the validation spectra was interspersed with acquisition of the calibration spectra, at the corresponding "Vn" positions.
- FIG. 8A depicts the data from Tables 5A, 5B and 6 graphically. The line in the Figure is the model prediction. The calculated R 2 value was 0.999, with a standard error of 2.78%.
- Example 4 The procedure described in Example 4 was followed, except as noted, sampling this time from the Reactor 2 polymer. Two hundred ninety-one polymer samples were evaluated. The samples were divided into a group of 266 used for calibration (model development) and a group of 25 used for model validation. Each sample was a Ziegler-Natta-catalyzed LLDPE resin, in a melt index range of from less than 1 to about 60 g/10 min. Raman spectra and laboratory melt index measurements were collected as described above.
- Table 7A MI Calibration, Reactor 2 MI MI MI Ml MI Ml MI MI
- Table 8 MI Validation, Reactor 2 MI (Lab) MI (Model) MI (Lab) MI (Model) MI (Lab) MI (Model) MI (Lab) MI (Model) (dg/min) (dg/min) (dg/min) (dg min) (dg min) VI: 0,733 0,771 17.291 17.738 23.390 22.991 0.754 0.782 17.896 18.229 V5: 1.907 1.915 0.798 0.810 20.620 20-046 1.908 1.946 0.727 0.718 V3: 52.180 51,199 1.958 1.976 0.721 0.750 52.020 54.219 1,902 1.911
- V2 17.649 18.223
- V4 24.880 24.521 1.930 1.979 18.399 18.519 20.760 20.008 1.930 1.947 19.844 19.492 18.667 18.903 21.480 21.018 16.682 16.822
- Figure 8B depicts the data from Tables 7A, 7B and 8 graphically.
- the line in the Figure is the model prediction.
- the calculated R 2 value was 0-997, with a standard error of 2.86%.
- Examples 6-7 demonstrate the effectiveness of the inventive methods online in a polymerization reaction system, for density determination.
- the measurements were carried out as described above in connection with Examples 4-5, except that a PCA LWR model was developed for density. The samples used, and spectra acquired, are a subset of those of Examples 4-5. Laboratory measurements of density were made on the samples in addition to the melt index measurements described above.
- Example 6 Density Model. Reactor 1 [0156] One hundred forty-six polymer samples were evaluated. The samples ere divided into a group of 109 used for calibration (model development) and a group of 37 used for model validation. Each sample was a metallocene-catalyzed LLDPE resin, in a density range of from about 0.912 to about 0.921 g cra 3 .
- Figure 9A depicts the data from Tables 9 and 10 graphically.
- the line in the Figure is the model prediction.
- the calculated R 2 value was 0.978, with a standard error of 0.00028 g cm 3 .
- Example 7 Density Model. Reactor 2 [0160] The procedure described in Example 6 was followed, except as noted, sampling this time from the Reactor 2 polymer. One hundred sixty-four polymer samples were evaluated. The samples were divided into a group of 151 used for calibration (model development) and a group of 13 used for model validation. Each sample was a Ziegler-Natta-catalyzed LLDPE resin, in a density range of f om about 0.916 to about 0.927 g/cm 3 . Raman spectra and laboratory density measurements were collected as described above.
- Table 11A Density (p, gcm 3 ) Calibration, Reactor2 p(Lab) P(Model) p(Lab) p(Model) p(Lab) p(Model) 0.9182 0.9182 2 0.9269 0,9270 0.9181 0.9184 0.9180 0.9184 0.9267 0.9268 0.9180 0,9178 0.9207 0.9209 0.9259 0.9263 0.9180 0.9179 0.9220 0.9225 0.9246 0.9249 0.9176 0.9180 0.9220 0.9221 0.9235 0.9235 0.9178 0.9182 0.9220 0,9217 0.9246 0.9250 0.9178 0.9179 0.9218 0.9219 0.9248 0.9246 0,9190 0.9187 0.9218 0.9219 0.9256 0.9257 0.9197 0.9192 0.9217 0.9217 0.9251 0.9253 0.9184 0.9178 0.9220 0.9220 0.9246 0.9246 0.9184 0.9190 0.9226 0.9221 0.9253 0.9253 0.9199 0.9198 0.92
- V2 0.9254 0.9257 0.9228 0.9230 0.9250 0.9247
- V4 0.9182 0.9180
- Figure 9B depicts the data from Tables 11 A, 11B and 12 graphically.
- the line in the Figure is the model prediction,
- the calculated R 2 value was 0.989, with a standard error of 0.00034 g/cm 3 .
- Examples 8-9 demonstrate the effectiveness, precision and accuracy of processes of the invention to predict melt index and density on-line, in a commercial-scale fluidized-bed polymerization reactor.
- the Raman system was as described above but used a 400 mW diode laser operating at 785 nm.
- the fiber optic cable used to couple the electrical components of the instrument to the Raman probe was a 62 ⁇ m excitation/1 OO ⁇ m collection step index silica fiber.
- Melt index and density models were developed by continuously collecting, and saving Raman data as individual spectra every 3-10 minutes, on each of two reactors. Validation of each model was accomplished by then using the model online to determine the polymer properties.
- Example 8 Polymer melt index was predicted on-line in a commercial-scale fluidized- bed reactor forming various grades of polyethylene copolymer. The prediction was carried out approximately every 12 minutes for about 5 weeks, Nearly 500 samples were also tested the laboratory, using the standard ASTM D-1238, condition E (2.16 kg load, 190 °C) protocol. The results, are shown in Table 13, where "Ml model” indicates the melt index 12.16 predicted by the model, and "MI lab” indicates the value obtained in the laboratory by the ASTM method. The same data are shown graphically in Figure 10, except that the Figure also shows the predicted MI for samples not corresponding to lab measurements. The predicted MI values are spaced sufficiently closely in time that they appear in the Figure to be a line. Table 13 Time Ml MI lab Time MI MI lab Time Ml MI lab Time MI Mi l*
- Table 13 and Figure 10 show the accuracy and precision of the on-line process over a long period of time, and a range of melt index values.
- the gaps in the Figure indicate periods when the reactor was down.
- the horizontal regions indicate continued production of a particular grade, and the steep vertical regions correspond to transitions between different grades.
- the data further show that the inventive on-line processes are accurate and precise even during grade transitions.
- the 3 ⁇ accuracy of the predictions relative to the lab values over the entire 5- week period was ⁇ 0.069 g/10 min.
- the predicted MI of approximately 2200 samples of a particular grade was monitored for a static sample over a four-week period, in each of two commercial-scale fluidized bed reactors. In each reactor, the data showed a 3 ⁇ standard deviation of 0.012 g/10 min (for sample with melt indexes of 1.0 and 0.98 g/10 min; i.e., about 1%), and no measurable long-term drift.
- Table 14 and Figure 11 show the accuracy and precision of the on-line process over a long period of time, and a range of density values.
- the gaps in the Figure indicate periods when the reactor was down, the horizontal regions indicate continued production of a particular grade, and the steep vertical regions correspond to transitions between different grades.
- the data further show that the inventive on-line processes are accurate and precise even during grade transitions.
- the 3 ⁇ accuracy of the predictions relative to the lab values over the entire 5-week period was ⁇ 0.00063 g/cm 3 .
- the predicted density of the same approximately 2200 samples of Example 8 was monitored for a static sample over a four- week period, in each of two commercial-scale fluidized bed reactors. In each reactor, the data showed a 3 ⁇ standard deviation of 0.00006 g/cm 3 (for samples with densities of 0.9177 and 0.9178 g/cm 3 ), and no measurable long-term drift.
- One preferred embodiment is a process for determining polymer properties in a polymerization reactor system, the process comprising: (a) obtaining a regression model for determining a polymer property, the regression model including principal component loadings and principal component scores; (b) acquiring a Raman spectrum of a sample comprising polyolefin; (c) calculating a new principal component score from at least a portion of the Raman spectrum and the principal component loadings; and (d) calculating the polymer property by applying the new principal component score to the regression model.
- the step of obtaining a regression model comprises: (i) obtaining a plurality of Raman spectra of samples comprising polyolefins; (ii) calculating principal component loadings and principal component scores from the spectra obtained in (i) using principal component analysis (PCA); and (iii) forming the regression model using the principal component scores calculated in (ii) such that the regression model correlates the polymer property to the principal component scores; wherein the regression model is a locally weighted regression model; wherein the polymer property is selected from density, melt flow rate, molecular weight, molecular weight distribution, and functions thereof; wherein the sample comprises polyolefin particles; wherein the step of acquiring a Raman spectrum comprises: (i) providing the sample of polyolefin particles; and (ii) irradiating the sample and collecting scattered radiation during a sampling interval using a sampling probe, wherein there is relative motion between the sample and the sampling probe during at least
- Another preferred embodiment is a process for determining polymer properties in a fluidized-bed reactor system, the process comprising: (a) obtaining a locally weighted regression model for determining a polymer property selected from density, melt flow rate, molecular weight, molecular weight distribution, and functions thereof, the locally weighted regression model including principal component loadings and principal component scores; (b) acquiring a Raman spectrum of a sample comprising polyolefin particles; (c) calculating a new principal component score from at least a portion of the Raman spectrum and the principal component loadings; and (d) calculating the polymer property by applying the new principal component score to the locally weighted regression model.
- the step of obtaining a regression model comprises: (i) obtaining a plurality of Raman spectra of samples comprising polyolefins; (ii) calculating principal component loadings and principal component scores from the spectra obtained in (i) using principal component analysis (PCA); and (iii) forming the regression model using the principal component scores calculated in (ii) such that the regression model correlates the polymer property to the principal component scores; wherein the step of acquiring a Raman spectrum comprises: (i) providing the sample of polyolefin particles; and (ii) irradiating the sample and collecting scattered radiation during a sampling interval using a sampling probe, wherein there is relative motion between the sample and the sampling probe during at least a portion of the sampling interval; wherein the process further comprises (i) obtaining a second regression model for determining a second polymer property, the second regression model including second principal component loadings and second principal component scores; (ii) calculating a
- Yet another preferred embodiment is a process for controlling polymer properties in a polymerization reactor system, the process comprising: (a) obtaining a regression model for determining a polymer property, the regression model including principal component loadings and principal component scores; (b) acquiring a Raman spectrum of a sample comprising polyolefin; (c) calculating a new principal component score from at least a portion of the Raman spectrum and the principal component loadings; (d) calculating the polymer property by applying the new principal component score to the regression model; and (e) adjusting at least one polymerization parameter based on the calculated polymer property.
- the step of obtaining a regression model comprises: (i) obtaining a plurality of Raman spectra of samples comprising polyolefins; (ii) calculating principal component loadings and principal component scores from the spectra obtained in (i) using principal component analysis (PCA); and (iii) forming the regression model using the principal component scores calculated in (ii) such that the regression model correlates the polymer property to the principal component scores; wherein the regression model is a locally weighted regression model; wherein the polymer property is selected from density, melt flow rate, molecular weight, molecular weight distribution, and functions thereof; wherein the sample comprises polyolefin particles; wherein the step of acquiring a Raman spectrum comprises: (i) providing the sample of polyolefin particles; and (ii) irradiating the sample and collecting scattered radiation during a sampling interval using a sampling probe, wherein there is relative motion between the sample and the sampling probe during at least
- the process further comprising: (i) obtaining a second regression model for determining a second polymer property, the second regression model including second principal component loadings and second principal component scores; (ii) calculating a new second principal component score from at least a portion of the Raman spectrum and the second principal component loadings; and (iii) calculating the second polymer property by applying the new second principal component score to the second regression model, and wherein the step of adjusting comprises adjusting at least one polymerization parameter based on the calculated polymer property, the calculated second polymer property, or both calculated polymer properties.
- Yet still another preferred embodiment is a process for controlling polymer properties in a fluidized reactor system, the process comprising: (a) obtaining a locally weighted regression model for determining a polymer property selected from density, melt flow rate, molecular weight, molecular weight distribution, and functions thereof, the locally weighted regression model including principal component loadings and principal component scores; (b) acquiring a Raman spectrum of a sample comprising polyolefin particles; (c) calculating a new principal component score from at least a portion of the Raman spectrum and the principal component loadings; (d) calculating the polymer property by applying the new principal component score to the locally weighted regression model; and (e) adjusting at least one polymerization parameter based on the calculated polymer property.
- the step of obtaining a regression model comprises: (i) obtaining a plurality of Raman spectra of samples comprising polyolefins; (ii) calculating principal component loadings and principal component scores from the spectra obtained in (i) using principal component analysis (PCA); and (iii) forming the regression model using the principal component scores calculated in (ii) such that the regression model correlates the polymer property to the principal component scores; wherein the step of acquiring a Raman spectrum comprises: (i) providing the sample of polyolefin particles; and (ii) irradiating the sample and collecting scattered radiation during a sampling interval using a sampling probe, wherein there is relative motion between the sample and the sampling probe during at least a portion of the sampling interval; wherein the at least one polymerization parameter is selected from the group consisting of monomer feed rate, comonomer feed rate, catalyst feed rate, hydrogen gas feed rate, and reaction temperature; the process further comprising:
- An even more preferred embodiment of the invention includes any of the foregoing preferred embodiments, with or without the more preferred embodiments, wherein the Raman probe is inserted in situ into the polymerization reactor system, especially in a location where granular polymer is moving, for example inserted directly into the reactor body.
- Embodiments of this even more preferred embodiment include the following, either alone or in combination: wherein the polymerization reactor system is a gas phase polymerization reactor system; wherein the reactor body 22 is a fluidized bed reactor; wherein the Raman probe is purged with a stream of, for instance, N 2 or ethylene; wherein the aforementioned period of purging is cycled with a period of data collection; wherein the Raman probe is inserted in situ into at least one of the locations within the polymerization reactor system selected from the reactor body, the cycle gas piping, the product discharge system downstream of the reactor body, in the cyclone, in the purger/degasser, in the transfer line to finishing/pack-out, and in the feed bins to the extruder; and wherein the step of acquiring a Raman spectrum comprises: (ii) irradiating the sample of polymer, e.g., polyolefin, and collecting scattered radiation during a sampling interval using a Raman probe, and (ii) purging polymer from said
- a yet still more preferred embodiment of the foregoing even more preferred embodiment includes: (A) a gas phase polymerization reactor wherein gaseous monomer is introduced into a reactor body and polymer is discharged from the reactor, the improvement comprising a Raman probe inserted directly into said reactor body, whereby a Raman spectrum correlated to at least one polymer property is obtained; and (B) a gas phase polymerization process wherein gaseous monomer is introduced into a reactor body, and polymer is produced in said reactor body and polymer product is discharged from the reactor, the improvement comprising measuring at least one property of the polymer produced in said reactor body by acquiring a Raman spectrum of said polymer within said reactor body.
- (B) include: wherein said Raman spectrum is acquired by inserting a Raman probe directly into said reactor body, and an optional probe purge, wherein said Raman probe is purged of polymer product by, for instance, a stream of nitrogen, ethylene (or monomer(s) used in the polymerization reaction), hydrogen, and the like.
- the process also can include, among other variations that would be readily apparent to one of ordinary skill in the art with the present disclosure before them, (a) obtaining a regression model for determining a polymer property, the regression model including principal component loadings and principal component scores; (b) acquiring a Raman spectrum of a sample comprising polyolefin; (c) calculating a new principal component score from at least a portion of the Raman spectrum and the principal component loadings; and (d) calculating the polymer property by applying the new principal component score to the regression model; and further may comprise at least one polymerization parameter based on the polymer property, in moreover another very preferred embodiment wherein the at least one polymerization parameter is selected from at least one of the group consisting of monomer feed rate, comonomer (if present) feed rate, catalyst feed rate, hydrogen gas feed rate, reaction temperature. [0179] Possibly the most advantageous improvement provided by the present invention is illustrated by the following additional more preferred embodiment:
- a gas phase polymerization process including a polymerization reactor system wherein gaseous monomer is introduced into a reactor body, polymer is produced in said reactor body, and polymer product is discharged from the reactor, the improvement comprising acquiring a Raman spectrum correlated with at least one property selected from the group consisting of a polymer property and a reactor operability property; and including the following embodiments, whose features may be combined: wherein said Raman spectrum is acquired by a Raman probe inserted in situ into said polymerization reactor system, such as wherein the Raman probe is inserted in situ into at least one of the locations within said polymerization reactor system selected from the group consisting of a polymerization reactor body, cycle gas piping, product discharge system downstream of the polymerization reactor body, a purger/degasser, a transfer line to finishing/pack-out, a feed bin to the extruder; wherein the process further comprises purging polymer from said Raman probe, such as wherein said purging comprises purging with a stream of nitrogen
- Preferred embodiments also include the apparatus including both the extractive sampling case as illustrated by Figure 2 and the in situ case described in detail above and includes: a gas phase polymerization reactor system, wherein gaseous monomer is introduced into a reactor body and polymer is discharged from the reactor, the improvement comprising providing a Raman probe in an extractive sampling system whereby a Raman spectrum correlated to at least one property selected from the group consisting of a polymer property and a reactor operability property is obtained, and more specifically wherein the extractive sampling system extracts polymer from a location selected from the group consisting of the cycle gas piping, the product discharge system downstream of the exiting point of product, the transfer line between the product discharge system and the purger(s)/degasser(s), one or more of the purger(s)/degasser(s), the transfer line to fmishing/pack-out, and the feed bins to the extruder/mixer; and also a gas phase polymerization reactor system wherein gaseous monomer is introduced
- the probe purge may be accomplished using a stream of nitrogen gas, monomer used in the polymerization reaction, or a combination of the two together or separately at different times and/or intervals.
- the sampling e.g., as illustrated by Fig. 2
- the sampling may be from one or more of the specific locations noted above for the in situ sampling case.
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Abstract
Description
Claims
Priority Applications (7)
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EP03818863A EP1578814A2 (en) | 2002-10-15 | 2003-05-08 | On-line measurement and control of polymer properties by raman spectroscopy |
EA200500611A EA009717B1 (en) | 2002-10-15 | 2003-05-08 | On-line measurement and control of polymer properties by raman spectroscopy |
CA002501528A CA2501528A1 (en) | 2002-10-15 | 2003-05-08 | On-line measurement and control of polymer properties by raman spectroscopy |
AU2003304552A AU2003304552A1 (en) | 2002-10-15 | 2003-05-08 | On-line measurement and control of polymer properties by raman spectroscopy |
JP2005510797A JP2006517987A (en) | 2002-10-15 | 2003-05-08 | Online measurement and control of polymer properties by Raman spectroscopy |
US10/528,894 US20060136149A1 (en) | 2002-10-15 | 2003-05-08 | On-line measurement and control of polymer properties by raman spectroscopy |
BR0315318-5A BR0315318A (en) | 2002-10-15 | 2003-05-08 | Online measurement and control of polymer properties through Raman spectroscopy |
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PCT/US2002/032767 WO2003042646A2 (en) | 2001-11-09 | 2002-10-15 | On-line measurement and control of polymer properties by raman spectroscopy |
USPCT/US02/32767 | 2002-10-15 |
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- 2003-05-08 BR BR0315318-5A patent/BR0315318A/en not_active IP Right Cessation
- 2003-05-08 WO PCT/US2003/014565 patent/WO2005049663A2/en active Application Filing
- 2003-05-08 US US10/528,894 patent/US20060136149A1/en not_active Abandoned
- 2003-05-08 EP EP03818863A patent/EP1578814A2/en not_active Withdrawn
- 2003-05-08 KR KR1020057006605A patent/KR20060024318A/en not_active Application Discontinuation
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Also Published As
Publication number | Publication date |
---|---|
JP2006517987A (en) | 2006-08-03 |
EA200500611A1 (en) | 2006-06-30 |
EA009717B1 (en) | 2008-02-28 |
CN1714106A (en) | 2005-12-28 |
CA2501528A1 (en) | 2004-04-15 |
BR0315318A (en) | 2005-08-16 |
EP1578814A2 (en) | 2005-09-28 |
AU2003304552A1 (en) | 2005-06-08 |
KR20060024318A (en) | 2006-03-16 |
US20060136149A1 (en) | 2006-06-22 |
CN100415779C (en) | 2008-09-03 |
WO2005049663A3 (en) | 2005-07-28 |
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