PROFILE REACTOR FOR OPERANDO MEASUREMENTS

Abstract

The invention pertains to a system for operando measurements that comprises, a reactor (1) comprising a reactor chamber (9) having at least one window (19) transparent for radiation for irradiating a sample (24) provided inside the reaction chamber (9), a radiation source (21, 31) for generating the radiation for irradiating the sample (24), wherein the radiation source (21, 31) is arranged to irradiate the sample at an irradiation location situated on the sample; a detection unit (26, 33) for detecting radiation scattered, emitted, reflected or diffracted by the sample (24) or transmitted through said sample (24), a sampling capillary (12) comprising an orifice (14) for collecting a fluid sample inside the reactor chamber (9), wherein the orifice (14) of the sampling capillary (12) is arranged at a fixed position relative to the irradiation location,
wherein the reactor (1) is movable relative to the radiation source (21, 31).

Claims

1.-10. (canceled)

11. A system for operando measurements comprising: a reactor (1) comprising a reactor chamber (9) having at least one window (19) transparent (transmissive) for radiation for irradiating a sample (24) provided inside the reaction chamber (9); a radiation source (21, 31) for generating the radiation for irradiating the sample (24), wherein the radiation source (21, 31) is arranged to irradiate the sample at an irradiation location situated on the sample; a detection unit (26, 34) for detecting radiation scattered, emitted, reflected or diffracted by the sample (24) or transmitted through said sample (24); a sampling capillary (12) comprising an orifice (14) for collecting a fluid sample inside the reactor chamber (9), wherein the orifice (14) of the sampling capillary (12) is arranged at a fixed position relative to the irradiation location; wherein the reactor (1) is movable relative to the radiation source (21, 31).

12. The system according to claim 11, wherein the radiation source (21) is arranged stationary and the reactor (1) is arranged movably.

13. The system according to claim 11, wherein the reactor (1) is movable in a longitudinal direction (3) of the reactor chamber (9).

14. The system according to claim 11, wherein the sampling capillary (12) is traversing the reactor chamber (9) and the orifice (14) is arranged in a side wall of the sampling capillary (12).

15. The system according to claim 11, wherein the orifice (14) is arranged inside the reactor chamber (9) when the reactor (1) is in a position of maximum deflection.

16. The system according to claim 11, wherein the sampling capillary (12) is arranged stationary.

17. The system according to claim 11, wherein a temperature-sensitive sensor (17) is arranged in the reactor chamber (9), wherein the temperature-sensitive sensor has the form of a pyrometer fiber (17) or a thermocouple (17) comprising a tip (18) for sensing a temperature.

18. The system according to claim 17, wherein the pyrometer fiber or thermocouple (17) is arranged inside the sampling capillary (12) and the tip (18) of the pyrometer fiber or thermocouple (17) is arranged at the orifice (14) of the sampling capillary (12).

19. A method for analyzing a sample comprising the steps of (1) Providing a system according to claim 11; (2) Arranging a sample (24) inside the reactor chamber (9); (3) Flowing a fluid through the reactor chamber (9) that reacts on or with the sample (24); (4) Positioning reactor (1) in a first position; (5) Taking a fluid sample from the fluid flown through the reactor chamber (9) at the first position by means of the sampling capillary (12) and analyzing said fluid sample; (6) Irradiating the sample (24) arranged inside the reactor chamber (9) at the first position by directing radiation emitted from the radiation source (21, 31) to a irradiation location on the sample (24); (7) Detecting radiation scattered, emitted, reflected or diffracted by the sample (24) arranged inside the reactor chamber (9) or transmitted through the sample (24) at the first position; (8) Analyzing the sample state based on evaluation of the radiation scattered emitted, reflected or diffracted by the sample (24) or transmitted through the sample (24); (9) Moving the reactor (1) into a position distant to the first position; (10) Repeating steps (6) to (9) until a last position is reached.

20. A method according to claim 19, wherein a temperature of the fluid or of the sample is measured at a position of the orifice (14) of the sampling capillary (12) while taking a fluid sample or irradiating the sample.

Description

[0123] The system according to the invention will be described in further detail with reference to the accompanying figures, wherein shows:

[0124] FIG. 1: a system according to a first embodiment comprising a reactor according to the invention wherein spectroscopic analysis is made by Raman-spectroscopy;

[0125] FIG. 2: a system according to a second embodiment comprising a reactor wherein analysis of a sample is made by X-ray diffraction;

[0126] FIG. 3: a spatially resolved profile of the temperature and composition of the gas phase as determined in the reactor according to the invention.

[0127] FIG. 1 is a schematic presentation of a system according to the invention wherein Raman-spectroscopy is used as exemplary method for analysis of a sample provided in the reactor chamber and forming a stationary phase.

[0128] A heatable reactor 1 is mounted on a table 2 that can be shifted along a longitudinal direction 3. The table is mounted on supports 4 which are slidably mounted on rails 5. A spindle 6 is connected to a motor 7 for rotating the spindle. The spindle 6 is provided with a screw thread that interacts with a corresponding screw thread mounted to table 2. By rotating spindle 6, table 2 can be moved back and forward along a longitudinal direction 3. Table 2 is provided with a cooling device (not shown) to absorb heat emitted from reactor 1. The reactor 1 comprises a thermally insulated reactor case 8 surrounding a reactor chamber 9. The reactor case 8 acts as an insulation for reactor chamber 9 and can be equipped with a heating or cooling device (not shown) for controlling the temperature of the reactor chamber 9. An inlet 10 and an outlet 11 is provided to introduce a fluid phase, e.g. a gaseous phase, into reaction chamber 9 on one side and to let out the fluid phase on the opposite side to generate a plug flow through reactor chamber 9. A sampling capillary 12 is traversing reaction chamber 9. Seals 13 are provided close to the reactor inlet 10 and the reactor outlet 11 in which is inserted sampling capillary 12 which allows a movement of reactor 1 along a longitudinal direction 3 while sampling capillary 12 is kept stationary. Sampling capillary 12 is provided with an orifice 14 for taking a fluid sample from the reactor chamber 9. The fluid sample then travels inside sampling capillary 12, e.g. due to a pressure gradient inside the sampling capillary, to arrive at an end 15 of sampling capillary 12 which is connected to e.g. a gas chromatograph (not shown) for analysis of the fluid sample. Through opposite end 16 of sampling capillary 12 is introduced a pyrometer fiber 17, or alternatively a thermocouple, with its tip 18 located at orifice 14. Pyrometer fiber 17 is connected to an evaluation unit (not shown) for displaying a temperature value. Reactor 1 is equipped with a window 19 with a length equal to the length of the reactor chamber 9 which is transparent for a radiation beam 20 generated e.g. by a laser 21. Radiation beam 20 emitted by laser 21 passes a beam splitter 22 and is then focused by a lens system 23 to be directed onto a sample 24, e.g. a catalyst bed, inserted into reactor chamber 9. During interaction of beam 20 with sample 24 part of the radiation is scattered and then is collected by lens system 23 to then pass beam splitter 22 in a linear direction. The scattered radiation then passes a notch filter 25 to remove light of a wavelength emitted by laser 21. Only radiation generated by Raman-scattering then is focused onto a detector 26 by a lens system 27 and a pinhole blend 28. The radiation generated by Raman-scattering is then analyzed by an evaluation unit 29 and displayed by a display unit 30.

[0129] For obtaining a profile of sample 24 in a longitudinal direction 3, table 2 is moved by action of motor 7 and spindle 6 to shift reactor 1 along a longitudinal direction 3. Since sampling capillary 12, tip 18 of pyrometer fiber 17 and beam 20 are kept in a stationary position while shifting reactor 1 positioned on table 2 in a longitudinal direction 3, a longitudinal profile of sample 24 positioned in reactor chamber 9 can be obtained for composition of the fluid phase, temperature of sample 24 and spectroscopic properties of sample 24 at the same time.

[0130] In FIG. 2 is displayed a system according to the invention adapted for use of X-ray diffraction for analyzing a sample. FIG. 2a is a view along a longitudinal direction, i.e. along a shifting direction of reactor 1 and FIG. 2b shows a view perpendicular to the longitudinal shifting direction of reactor 1. Same numerals designate same parts of the system according to the invention.

[0131] Reactor 1 basically has the same configuration as the reactor described in FIG. 1. Reactor 1 comprises a reactor chamber 9. Reactor 1 is mounted on table 2 which is slidably mounted on rails 5 to be movable along a longitudinal direction 3. A sampling capillary 12 is traversing reactor chamber to collect a fluid sample inside reactor chamber 9 for analysis. A window 19 is provided on one side of the reactor chamber 9 which is transmissive for X-rays. An X-ray source 31 is provided which emits an X-ray beam 32 and can be moved on a segment of a circle 33. The X-ray beam 32 interacts with sample 24 to be diffracted. The diffracted parts of X-ray beam are collected in an X-ray detector 34 that is movable on a segment of a circle 33. The reflexes collected by the X-ray detector may then be further processed by a corresponding evaluation unit (not displayed) and displayed by a suitable display unit (not displayed).

[0132] FIG. 2a shows the Bragg-Brentano geometry for arrangement of the sample surface, x-ray source and X-ray detector. The sample surface is arranged in the center of the focusing circle 33. X-ray source 31 and X-ray detector 34 are moved on the focusing circle 33.

[0133] FIG. 3 shows a profile of a concentration distribution and a temperature distribution as detected with a system as shown in FIG. 1. Ethane was oxidatively dehydrogenated to ethylene on a VO.sub.x/Al.sub.2O.sub.3 catalyst at a temperature of 500 C.

[0134] At the reactor inlet (0 mm) concentration of reactants ethane and oxygen is high. When moving along the reaction coordinate in a longitudinal direction of the reactor the concentration of ethane and oxygen decreases while products water, carbon monoxide, ethylene and carbon dioxide are formed. Temperature within the reactor chamber increases to reach a hot spot at about 9 mm. Temperature then decreases again due to the low oxygen concentration.

LIST OF REFERENCE NUMBERS

[0135] 1 reactor [0136] 2 table [0137] 3 longitudinal direction [0138] 4 supports [0139] 5 rail [0140] 6 spindel [0141] 7 motor [0142] 8 reactor case [0143] 9 reactor chamber [0144] 10 inlet [0145] 11 outlet [0146] 12 sampling capillary [0147] 13 seals [0148] 14 orifice [0149] 15 end of sampling capillary [0150] 16 end of sampling capillary [0151] 17 pyrometer fiber or thermocouple [0152] 18 tip of pyrometer fiber or of thermocouple [0153] 19 window [0154] 20 radiation beam [0155] 21 laser [0156] 22 beam splitter [0157] 23 lens system [0158] 24 sample [0159] 25 notch filter [0160] 26 detector [0161] 27 lens system [0162] 28 pinhole [0163] 29 evaluation unit [0164] 30 display unit [0165] 31 X-ray source [0166] 32 X-ray beam [0167] 33 Segment of a circle [0168] 34 X-ray detector