System for testing catalysts at elevated pressures
A system for evaluating catalyst formulations at elevated pressures is disclosed. The system comprises a parallel reactor and a sensor for detecting catalytic activity of the catalyst formulations. The parallel reactor is adapted for providing reaction conditions that include pressure greater than one bar absolute, and comprises a multisample holder for supporting a plurality of different catalyst formulations, and a reaction chamber encasing the multisample holder, the reaction chamber comprising reactor walls and pressure-tight leads extending through the reactor walls for providing the elevated pressure. The parallel reactor can be a parallel batch reactor. The multicell holder can be, for example, a honeycomb or plate.
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1. Field of the Invention
The present invention relates to the general field of catalyst testing, generally classified in U.S. Patent Class 502 or 252.
II. Description of the Prior Art
Prior Art will include C & E News, Jan. 8, 1996, p. 30 which teaches reactive plastics, and the many catalyst testing devices and processes known to the petroleum refining art. F. M. Menger, A. V. Fliseev, and V. A. Migulin, “Phosphatase catalysts developed via combinatorial organic chemistry”, J. Org. Chem. Vol. 60, pp 6666-6667, 1995. Xiang, 268 Science 1738 and Bricenol, 270 Science 273, both on combinatorial libraries of solid-state compounds; Sullivan, Today's Chem. At Work 14 on combinatorial technology; Nessler 59 J. Org. Chem. 4723 on tagging of combinatorial libraries; Baldwin, 117 J. Amer. Chem. Soc. 5588 on combinatorial libraries.
II. Problems Presented by Prior Art
Catalyst testing is conventionally accomplished in bench scale or larger pilot plants in which the feed is contacted with a catalyst under reaction conditions, generally with effluent products being sampled, often with samples being analyzed and results subjected to data resolution techniques. Such procedures can take a day or more for a single run on a single catalyst. While such techniques will have value in fine-tuning the optimum matrices, pellet shape, etc., the present invention permits the scanning of dozens of catalysts in a single set-up, often in less time than required for a single catalyst to be evaluated by conventional methods. Further, when practiced in its preferred robotic embodiments, the invention can sharply reduce the labor costs per catalyst screened.
SUMMARY OF THE INVENTIONGeneral Statement of the Invention
According to the invention, a multisample holder (support) e.g. a honeycomb or plate, or a collection of individual support particles, is treated with solutions/suspensions of catalyst ingredients to fill wells in plates, or to produce cells, spots or pellets, holding each of a variety of combinations of the ingredients, is dried, calcined or otherwise treated as necessary to stabilize the ingredients in the cells, spots or pellets, then is contacted with a potentially reactive feed stream or batch e.g., to catalyze biochemical reactions catalyzed by proteins, cells, enzymes; gas oil, hydrogen plus oxygen, ethylene or other polymerizable monomer, propylene plus oxygen, or CCl2F2 and hydrogen. The reaction occurring in each cell is measured, e.g. by infrared thermography, spectroscopic, electrochemical, photometric, thermal conductivity or other method of detection of products or residual reactants, or by sampling, e.g. by multistreaming through low volume tubing, from the vicinity of each combination, followed by analysis e.g. spectral analysis, chromatography etc, or by observing temperature change in the vicinity of the catalyst e.g. by thermographic techniques, to determine the relative efficacy of the catalysts in each combination. Robotic techniques can be employed in producing the cells, spots. pellets) etc. Each of these parameters is discussed below.
Catalysts:
Biotechnology catalysts include proteins, cells, enzymes, etc. Chemical conversion catalysts include most of the elements of the Periodic Table which are solid at the reaction conditions. Hydrocarbon conversion catalysts include Bi, Sn, Sb, Ti, Zr, Pt, the rare earths, and many possible candidates whose potential has not yet been recognized for the specific reaction. Many synergistic combinations will be useful. Supported metals and metal complexes are preferred. The chemical catalysts can be added to the substrate (support) as elements, as organic or inorganic compounds which decompose under the temperature of the stabilizing step, depositing the element or its oxide onto the substrate, or as stable compounds.
Supports:
Supports can be inert clays, zeolites, ceramics, carbon, plastics, e.g. reactive plastics, stable, nonreactive metals, or combinations of the foregoing. Their shape can be porous honeycomb penetrated by channels, particles (pellets), or plates onto which patches (spots) of catalyst candidates are deposited or wells in plates. Conventional catalyst matrix materials such as zeolites e.g. zeolite USY, kaolin, alumina, etc. are particularly preferred as they can simulate commercial catalysts.
Preparation:
The catalyst candidate precursors can be deposited onto the supports by any convenient technique, preferably by pipette or absorbing stamp (like a rubber stamp), or silk screen. In preferred embodiments, the deposition process will be under robotic control, similar to that used to load multicell plates in biochemical assays. Many of the spots of catalyst will be built up by several separate depositions e.g. a channel penetrating a honeycomb can be plugged at one third of its length and the channel filled with a catalyst solution in its upper third, then the plug can be moved to the two-thirds point in the channel and a second catalyst pipetted in, then the plug can be removed and a third catalyst solution added, resulting in a channel in which reactants contact three catalysts successively as they flow through the channel. Catalyst can also be added by ion exchange, solid deposition, impregnation, or combination of these. The techniques of combinatorial chemical or biological preparation can preferably be utilized to prepare an array of candidate catalysts with the invention. Coprecipitates of two or more catalysts can be slurried, applied to the support, then activated as necessary. Catalysts can be silk screened onto a support plate or inside of a support conduit, and successive screenings can be used to add different catalyst combinations to different spots.
Stabilizing Step:
Once the catalysts are in place on the support, any suitable technique known to the art can be used to stabilize, and/or activate the particular catalysts chosen, so they will remain in place during the reaction step. Calcining, steaming, melting, drying, precipitation and reaction in place will be particularly preferred.
Reactants:
The Invention has utility with any reaction which can be enhanced by the presence of a catalyst, including biological reactions and inorganic and organic chemical reactions. Chemical reactions include polymerization reactions, halogenation, oxidation, hydrolysis, esterification, reduction and any other conventional reaction which can benefit from a catalyst. Hydrocarbon conversion reactions, as used in petroleum refining are an important use of the invention and include reforming, fluid catalytic cracking, hydrogenation, hydrocracking, hydrotreating, hydrodesulfurizing, alkylation and gasoline sweetening.
Sensors:
The sensors used to detect catalytic activity in the candidate catalysts are not narrowly critical but will preferably be as simple as practical. Chromatographs, temperature sensors, and spectrometers will be particularly preferred, especially those adapted to measure temperature and/or products near each specific catalyst spot e.g. by multistreaming, multitasking, sampling, fiber optics, or laser techniques. Thermography, as by an infrared camera recording the temperature at a number of catalyst sites simultaneously, is particularly preferred. Other suitable sensors include NMR, NIR, TNIR, electrochemical, fluorescence detectors, Raman, flame ionization, thermal conductivity, mass, viscosity and stimulated electron or X-ray emission Sensors can detect products in a gas or liquid stream or on the surface of the support.
Endothermic reactions exhibit reduced temperature at best catalysts. Some sensors employ an added detection reagent, e.g. ozone to impart chemiluminesce.
Taggants:
Optionally taggants (labels) can be added to identify particular catalysts, particularly where particles are employed as supports for the catalysts. These taggants can be conventional as discussed in the literature. Taggants can be chemicals which are stable at reaction conditions or can be radioactive with distinctive emissions. The techniques of combinatorial chemistry will be applicable with taggants as well as with catalysts chosen to suit the particular reaction to be enhanced by the catalyst.
Batch or Continuous:
While the invention will be preferred on a flow basis, with reactants flowing by the catalyst spots under reaction conditions, batch testing e.g. in a stirred autoclave or agitated containers, can be employed, particularly in biological reactions.
Temperatures, Pressures, Space Velocities and Other Reaction Conditions:
These will be determined by the reactants and reaction. Elevated pressures can be provided as reaction conditions by encasing the support in a reaction chamber with a sapphire or similar window for observation by the sensing means, or with pressure-tight leads extending through the reactor walls.
II. Utility of the Invention
The present invention is useful in the testing of catalysts for biotechnology, for promotion of gas phase and liquid phase reactions; under batch or, preferably, continuous flowstream conditions; at elevated, reduced or atmospheric pressure; and saves both elapsed time and labor in screening for improved catalysts to promote a desired reaction.
BRIEF DESCRIPTION OF THE DRAWINGS
Referring to
Catalysts are alternatively identified by conducting the reaction in the presence of strong ultraviolet and/or visible light illumination. with infrared thermography being conducted immediately after the illumination is turned off, or through the use of a short pass filter on the illumination source to eliminate contaminating infra-red radiation.
EXAMPLE 2 Referring to
Referring to
A collection of catalyst precursor compositions is produced by automated liquid handling device, and a catalyst support particle is contacted with each composition. After further treatment to stabilize and activate the catalyst precursors, catalyst pellets are arrayed on a surface, exposed to a potentially reactive environment and their activity determined by infrared thermography.
EXAMPLE 5Solutions of combinations of catalyst precursors are prepared in a variety of separate vessels. Each composition also contains a small quantity of a labeling material (e.g., stable isotopes of the element carbon or sulfur in varying ratios). Catalyst support particles are contacted with catalyst precursor preparations, and activated. Pellets are then contacted one at a time with a potentially reactive mixture (for example, by elutriation into an enclosed volume) and their activity measured (by thermography, by spectroscopic measurement of products, or sampling of the surrounding vapor or liquid phase). Particles showing activity are collected and individually analyzed for their content of the labeling material so as to determine the composition giving the desired catalytic activity.
EXAMPLE 6Example 2 is repeated except that only a portion of the pore length is coated with a catalyst candidate so as to allow for observation of unmodified monolith pore wall as a control reference standard for optical uniformity.
EXAMPLE 7The emissivity of the support monolith pores of the support 20 of Example 2 is mapped at a wavelength of interest by holding the monolith at the intended experimental temperature in reactants. Digitally stored maps of the emissivity are used to normalize the infra-red energy flux measured under experimental conditions, to improve the accuracy with which local temperatures can be estimated.
EXAMPLE 8A surface of high, substantially uniform emissivity is located at the end of the monolith of Example 2, away from the camera, in close radiative heat transfer/contact with the monolith channel material. The temperature of the portion of the surface closest to the open end of each channel is observed. In this case, it is necessary that gas be admitted into the channels past the uniform radiative surface, either by means of pores or by means of a small offset between the radiative surface and the monolith.
EXAMPLE 9 Alternatively, spots of catalysts can be deposited on the inner surface of a reactor e.g. a tube formed of the support material as shown in
The process of Example 1 is repeated except that the reactants are in the liquid phase and a liquid phase assay is used (
The experiment of Example 4 is repeated except that the metal loading is directly measured by dissolving the pellet and directly analyzing the metal loading.
EXAMPLE 12 A sheet of alpha alumina 5 in
A porous alumina monolith 140 in
The reactor is then fed with a gas mixture of 2.5 mole % oxygen in hydrogen 154. The reactor and feed temperatures are originally set to 40 degrees centigrade, and are gradually increased While the catalyst-bearing monolith is repeatedly imaged in the R. The temperature in each cell may be judged by observing the cell at a position adjacent to the end of the catalyst-precursor-coated section of the channel, or by normalizing the observed IR energy emission by the emissivity calculated from the images taken under nonreactive conditions. The compositions in the cells showing the earliest temperature increase above the reactor temperature are useful as hydrogen oxidation catalysts.
EXAMPLE 14 A porous alumina monolith 140 in
After drying and reduction in the presence of hydrogen gas, the activated monolith is placed into a reactor in which it can be observed through a sapphire window 172 using an IR-sensitive camera 170.
This first window 172 is positioned 0.5 centimeter from the surface of the monolith. The camera 170 is positioned in such a way as to look through the window 172, through the channels of the support and through a second sapphire window 174 toward a source of IR radiation 164.
The reactor 168 is then fed with methane gas, mixed with oxygen and argon, in such a way that the gas 165 flows through the channels of the monolith toward the camera. An optical filter 162 which selectively passes IR radiation at 4.3 microns, a wavelength which is strongly absorbed by carbon dioxide, is inserted between the IR source and the camera. The effective concentration of carbon dioxide in each channel is inferred from the IR intensity at 4.3 microns seen in that channel. The reading at 4.3 microns for each pixel is divided by the reading taken through a filter selective for an IR wavelength which is near 4.3 microns, but which is not absorbed strongly by carbon dioxide, methane or water, to compensate for potential optical artifacts.
Compositions giving high concentrations of carbon dioxide after long exposures to operating conditions are useful in catalytic oxidation of methane.
EXAMPLE 15Solutions of combinations of catalyst precursors are prepared in a variety of separate vessels. Each composition also contains a small quantity of a labeling material (e.g., stable isotopes of the element sulfur in varying ratios unique to each composition). Catalyst support particles are contacted with the preparations of catalyst precursor compositions, and activated. Pellets are then contacted one at a time with a potentially reactive mixture (for example, by elutriation into an enclosed volume) and their activity measured (by thermography, by spectroscopic measurement of products, or sampling of the surrounding vapor or liquid phase). Particles showing activity are collected and individually analyzed for their content of the labeling material so as to determine the composition giving the desired catalytic activity.
EXAMPLE 16 A Teflon block monolith 140 in
The catalyst-charged monolith is placed into a reactor in which it can be observed through a window 172, positioned 0.5 centimeter from the surface of the block. A camera 170 is positioned in such a way as to look via through the sapphire window, through the channels of the support and through a second window 174, toward a source of polarized light 164. A polarizer 162 is installed between the block and the camera.
A sucrose solution 166 is fed to the reactor in such a way as to flow through the channels of the block. The angle of rotation of polarized light in passing through the liquid in each channel is measured by rotating the polarizer to various angles, and observing the variation in brightness of the light passing through each channel. The candidate catalysts found in channels giving the greatest change in the angle of rotation are useful as catalysts of sucrose hydrolysis.
EXAMPLE 17Catalysts for photooxidation of hexane are identified by conducting the reaction in the apparatus of Example 16 in the presence of strong ultraviolet and/or visible light illumination, with infra-red thermography being conducted immediately after the illumination is turned off, or through the use of a short pass filter on the illumination source to eliminate contaminating infrared radiation.
EXAMPLE 18Samples of cyanogen bromide-activated cross linked agarose beads are exposed to solutions of alcohol oxidase at varied pHs, salt concentrations, and enzyme concentrations. After coupling of the enzyme, residual active groups are quenched with ethanolamine, the beads are washed, and each sample placed in a separate well of a multiwell plate. The plate is exposed to a flowing air stream containing ethanol vapor and observed with an Amber infrared-sensitive camera.
The samples showing the greatest temperature increase are selected as highly active immobilized alcohol oxidase catalysts.
EXAMPLE 19Samples of cyanogen bromide activated cross linked agarose beads are exposed to solutions of anti-alcohol oxidase antibodies at varied pHs, salt concentrations, and antibody concentrations. After coupling of the enzyme, residual active groups are quenched with ethanolamine. The beads are washed, exposed to a solution of alcohol oxidase) washed again, and each sample placed in a separate well of a multiwell plate. The plate is exposed to a flowing air stream containing ethanol vapor and observed with an Amber infrared-sensitive camera.
The samples showing the greatest temperature increase are selected as highly active immobilized alcohol oxidase catalysts.
EXAMPLE 20A ceramic monolith having channels arranged in perpendicular row/column format passing through its entire thickness is washcoated with porous alumina particles and all the channels in each column are treated with the same catalyst precursors, which are activated. A potentially-reactive stream is flowed through the channels of the monolith, and a multiwavelength beam of radiation is passed over the surface of the monolith, parallel to each column, to a detector situated at the end of the column. The composition of the stream leaving the pores in that column is estimated by processing the detector output, including. Fourier transformation and/or weighted summation/differencing of the intensities at different wavelengths.
EXAMPLE 21Pellets bearing catalytically-active groups capable of catalyzing the conversion of both the D- and L-stereoisomers of a reactant are treated with a variety of substances potentially capable of preferentially suppressing (temporarily or permanently) the conversion of the L-stereoisomer of that compound by that catalyst. The pellets are distributed among the wells of a multiwell plate and exposed to a mixture of the isomers of the compound to be modified. Pellets treated with the suppressor giving the greatest reduction in the activity for conversion of the L-isomer are useful in stereoselective modification of the D-isomer.
EXAMPLE 22A ceramic monolith having channels arranged in perpendicular row/column format passing through its entire thickness is washcoated with porous alumina particles and the channels treated with catalyst precursors, which are activated. A potentially-reactive stream is flowed through the channels of the monolith. A manifold consisting of an array of tubes, each smaller than the dimensions of an individual channel, is used to introduce a stream containing ozone into the stream flowing through each channel, near its outlet. Reaction of the introduced ozone with the desired product liberates light, which is detected by a camera directed at the monolith. The catalyst composition giving the strongest light output is a useful catalyst for conversion of the reactants to the ozone-reactive desired product.
EXAMPLE 23A ceramic monolith having channels arranged in perpendicular row/column format passing through its entire thickness is washcoated with porous alumina particles and the channels treated with catalyst precursors, which are activated and then exposed to a potentially deactivating substance. A potentially-reactive stream is flowed through the channels of the monolith. A manifold consisting of an array of tubes, each smaller than the dimensions of an individual channel 71 is used to sample the stream flowing within each channel. Samples from each channel in turn are introduced into a gas chromatograph-mass spectrometer combination through an arrangement of switching valves, and catalyst compositions giving the highest yield of desired products are useful in conversion of that reactive stream.
MODIFICATIONSSpecific compositions, methods, or embodiments discussed are intended to be only illustrative of the invention disclosed by this specification. Variations on these compositions, methods, or embodiments are readily apparent to a person of skill in the art based upon the teachings of this specification and are therefore intended to be included as part of the inventions disclosed herein. For example, statistically-designed experiments, and automated, iterative experimental process methods can be employed to obtain further reductions in time for testing. Attachment/arraying of preformed catalytic elements (especially precipitates, also single molecules and complexes such as metallocenes) onto a support, preferably by precipitating or deposition is useful in many cases.
Detection can involve addition of some reagent to the stream leaving each candidate, the reagent allowing detection of a catalyst product through staining or reaction to give a detectable product, light, etc.
The supports can comprise arrays with special arrangements for e.g., a header of multiple delivery tubes for uniform flow distribution, inserted into each channel in a block.
The detection means can comprise electrochemical means, or a gamma camera for metals accumulation measurement, imaging elemental analysis by neutron activation and imaging by film or storage plate of emitted radioactivity, temperature measurement by acoustic pyrometry, bolometry, electrochemical detection. conductivity detection, liquid phase assay, preferably dissolving the support pellet and directly analyzing the metal loading; measuring refractive index in the liquid phase; observing the IR emissions of product gases directly, without the usual source and using instead the radiation hot gases emit at characteristic wavelengths.
Other modifications can include testing for selectivity after deliberately poisoning some sites, especially in chiral catalysis, etc. The formulations can be supported in the form of spots or layers on the surface of a support containing wells or channels or channels extending across the entire extent of the support. The support can comprise a form of carbon, zeolite and/or plastic. The plastic can comprise a reactant. The support can hold a form of catalyst made by coprecipitation, or aluminum or particles.
At least one of the formulations can preferably comprise a material selected from the group consisting of transition metals, platinum,. iron, rhodium manganese, metallocenes, zinc, copper, potassium chloride, calcium, zinc, molybdenum, silver, tungsten, cobalt and mixtures of the foregoing.
The label can comprise different isotopes or different mixtures of isotopes.
The reaction conditions can comprise a pressure greater than one bar absolute pressure and the contact can be at a temperature greater than 100 degrees centigrade
The method can comprise detection of temperature changes in the vicinity of a respective formulation due to reaction endotherm or exotherm.
The method can comprise treatment with a reducing agent.
The contacting step can be carried out in the presence of compounds which modify the distribution of the metal within the porous support.
The candidate catalyst formulations can be contacted in the form of spots or layers on the surface of a support containing a washcoat supported by an underlayer.
The stabilizing step can be carried out with a temperature gradient or other means whereby certain candidate catalyst formulations are exposed to different temperatures. The stabilizing can comprise calcining, steaming, drying, reaction, ion exchange and/or precipitation.
The detection of temperature changes due to reaction can employ a correction for emissivity variations associated with differences in chemical composition.
The array of formulations to be tested can comprise preformed. metallocenes or other catalytic complexes fixed to a support.
The infrared radiation can be detected through the use of nondispersive infrared spectroscopy, or infrared-sensitive photographic film. The detector means can comprise means for physically scanning over an array of candidate formulations.
Observations at multiple wavelengths can be processed by mathematical manipulation e.g. transformation, weighted summation and/or subtraction, etc.
Reaction activity, reactants, or products can be detected through the use of an added reaction which signals the presence of reaction or particular compounds or classes of compounds.
Chemiluminescence can be used as an indicator of reaction activity, or particular compounds or classes of compounds.
A substantially collimated radiation source can be employed in product detection/imaging.
Multi-tube sampling can be used to lead into a mass spectrometer, chromatograph, or optical monitor.
To simulate aging, etc., the formulations can exposed to a deleterious agent which reduces the activity of at least one formulation by at least 10%, and then optionally exposed to steam, heat, H2, air, liquid water or other different substance(s) or condition(s) which increase the activity of at least one member of the collection by at least 10% over its previously-reduced activity whereby regenerability, reactivatability, decoking, or other catalyst property is measured. The deleterious agent can comprise elevated temperature, V, Pb, Ni, As, Sb, Sn, Hg, Fe, S or other metals, H2S, chlorine, oxygen, Cl, and/or carbon monoxide.
Reference to documents made in the specification is intended to result in such patents or literature being expressly incorporated herein by reference.
Claims
1. A system for testing a plurality of catalyst formulations at elevated pressures, the system comprising
- a parallel reactor adapted for providing reaction conditions comprising an elevated pressure greater than one bar absolute, the parallel reactor comprising (i) a multisample holder for supporting a plurality of different catalyst formulations, and (ii) a reaction chamber encasing the multisample holder, the reaction chamber comprising reactor walls and pressure tight leads extending through the reactor walls for providing the elevated pressure, and
- a sensor for detecting catalytic activity of the catalyst formulation.
2. The system of claim 1 wherein the parallel reactor is adapted for providing reaction conditions comprising a temperature greater than 100° C.
3. The system of claim 1 further comprising an automated liquid delivery system.
4. The system of claim 1 further comprising a pipette under robotic control.
5. The system of claim 1 wherein the sensor is selected from chromatographs, temperature sensors or spectrometers.
6. The system of claim 5 wherein the chromatographs, temperature sensors or spectrometers are adapted for measuring temperature or products near each catalyst formulation, for example by multistreaming, multitasking, sampling, fiber optics or laser techniques.
7. The system of claim 5 wherein the sensor is an infrared camera adapted for recording the relative temperature or heat absorption or emission at a number of catalysts formulations simultaneously.
8. The system of claim 5 wherein the sensor is a detector for Raman spectroscopy, FTIR spectroscopy, NMR spectroscopy, gas chromatography, mass spectroscopy, gas chromatography/mass spectroscopy, liquid chromatography and light emission spectroscopy.
9. The system of claim 5 further comprising an array of catalyst formulations supported separately on the multisample holder.
10. The system of claim 9 wherein the catalyst formulations comprise enzymes, chiral catalysts, inorganic oxides, transition metals or metallocenes.
11. The system of claim 1 where in the parallel reactor is a parallel batch reactor.
12. The system of claim 1 wherein the parallel reactor is a parallel batch reactor comprising agitated containers.
13. The system of claim 1 wherein the parallel reactor is a parallel stirred autoclave.
14. The system of claim 1 wherein the multisample holder comprises a honeycomb or a plate.
15. The system of claim 1 wherein the multisample holder comprises a plate having wells.
16. The system of claim 1 wherein the multisample holder comprises channels.
17. A method for using the system of claim 1 for testing catalyst formulations, the method comprising
- supporting the formulations separately on a multisample holder,
- encasing the multisample holder in the reaction chamber,
- contacting the supported formulations with the reactant or reactants under reaction conditions comprising a pressure of more than one bar absolute, and
- analyzing the products or reactants of the reactions catalyzed by the respective supported formulations to determine the relative efficacy of the candidate catalyst formulations.
18. The method of claim 14 wherein the reaction conditions comprise a temperature greater than 100° C.
19. The method of claim 14 further comprising statistically designing the experiment for testing the catalyst formulations.
20. The method of claim 14 wherein the catalyst formulations comprise enzymes, chiral catalysts, inorganic oxides, transition metals or metallocenes.
Type: Application
Filed: Mar 16, 2005
Publication Date: Jul 21, 2005
Applicant:
Inventor: Richard Willson, (Houston, TX)
Application Number: 11/081,429