DE20219279U1 - Tube bundle reactor for catalytic gas phase reactions, automatically bypasses recirculated heating medium in cold, viscous state, during start up - Google Patents

Abstract

During reactor (2) start up, heat exchange medium bypass (22) throughput, corresponds with a comparatively-cold and viscous state. In this case, the reactor vessel (8) is partially bypassed. During steady-state reactor operation, flow is automatically controlled as a function of the instantaneous heating power required in the reactor. In this case, heat exchange medium passes through the reactor at an essentially constant flow rate. Preferred Features: Control functions are carried out in a common unit. Bypassing is controlled on temperature and ranges of bypass ratio are specified for start-up and running conditions. Annular channels and openings form inlets and outlets for the heat exchange medium. A heater (30) is provided for the medium, and is used during start up. It is in e.g. a valved, auxiliary circuit in a location unrelated to the main medium inlet and outlet. An external heating medium is employed in a heater. Further details of the bypass, its valving and circulating pump (12) connections and disposition are provided. A mixer may be included. Conventional thermal expansion and de-gasification provisions are made. An additional pump mitigates against cavitation in the circulation pump. The design is further detailed.

Description

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The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically  

The description text was not recorded electronically

Claims (58)

1. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) for catalytic gas phase reactions, with a reaction vessel ( 8 ; 182 , 184 ; 208 ; 226 ) in the form of a surrounded by a reactor jacket and from a liquid heat carrier flushed reaction tube bundle, with at least one circulation pump ( 12 ; 230 ; 270 ; 280 ; 290 ) arranged outside the reaction container for the heat transfer medium, with at least one heat exchanger ( 16 ) connected in parallel with the circulation pump and with one by-circuit also connected in parallel with the circulation pump pass ( 22 ), characterized in that the heat transfer throughput through the bypass ( 22 ) in the start-up phase of the reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) while still relatively cold and correspondingly viscous heat transfer medium can be controlled in such a way that the reaction vessel ( 8 ; 182 , 184 ; 208 ; 226 ) is partially bypassed while it is in operation eb of the reactor is automatically regulated in dependence on the heat exchanger output to be provided in such a way that the heat carrier throughput passing through the reaction vessel remains essentially constant. 2. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 1, characterized in that the relevant control and regulating functions, possibly with other within the heat transfer circuit system, in are united by a common controller. 3. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 2, characterized in that the controller depending on the flow rate through the bypass ( 22 ) at least in the start-up phase of the reactor controls the heat transfer temperature. 4. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that the ratio of heat exchanger throughput and bypass throughput to the heat transfer throughput through the reaction tank ( 8 ; 182 , 184 ; 208 ; 226 ) in stationary operation is between 2 and 50% by volume, preferably between 6 and 25% by volume. 5. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that the regulation of the heat transfer throughput by the bypass ( 22 ) in the stationary operation of the reactor one such is that the heat carrier throughput passing through the reaction container ( 8 ; 182 , 184 ; 208 ; 226 ) deviates less than ± 20% from the projected nominal value. 6. tubular reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that it at least in the region of both ends of the Re reaction container ( 8 ; 182 , 184 ; 208 ; 226 ) ring channels ( 4 , 6 ; 202 ; 222 ; 240 , 242 ; 244 , 246 ) with windows ( 210 ) to the inside of the reaction vessel for the supply and discharge of the heat carrier. 7. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that within the heat transfer circuit egg nen heater ( 30 ) for heating the heat transfer medium in the start-up phase of the reactor. 8. jacket tube reactor ( 2 ) according to claim 7, characterized in that the heater ( 30 ) is in its own, optionally valve-controlled shunt circuit ( 28 ). 9. jacket tube reactor ( 2 ) according to claim 8 in connection with claim 5, characterized in that the heating circuit ( 30 ) containing the shunt circuit ( 28 ) at one of that of the extraction and feed point of the main heat transfer circuit (10, 12, 14 etc.) different point is connected to the ring channels ( 4 , 6 ). 10. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that its heat transfer circuit system can be fed with externally heated heat transfer medium. 11. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that the bypass ( 22 ) on the part of the circulation pump ( 12 ; 230 ; 270 ; 280 ; 290 ) seen from the shunt circuit ( 18 ) of the heat exchanger ( 16 ) is arranged. 12. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 11, characterized in that the bypass ( 22 ) and / or the branch containing the heat exchanger ( 16 ) is valve-controlled , 13. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 12, characterized in that the bypass ( 22 ) and the branch containing the heat exchanger ( 16 ) by a common multi-way valve ( 34 ; 68 ; 100 ; 108 ) are controlled. 14. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 13, characterized in that the multi-way valve ( 34 ; 68 ; 100 ; 108 ) is a pressure-relieved slide valve. 15. jacket tube reactor ( 50 ; 90 ) according to claim 13 or 14, characterized in that the bypass ( 22 ) in the reusable valve ( 68 ; 108 ) is integrated. 16. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that at least one of the partial flow merging points in the heat transfer circuit with a mixer ( 38 , 40 ) is equipped. 17. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims including claim 6, characterized in that a mixer in at least one of the ring channels ( 4 , 6 ; 202 , 204 , 206 ; 222 ; 240 , 242 , 244 , 246 ) is installed. 18. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims including claims 6 and 11, characterized in that the bypass ( 22 ) and heat exchanger ( 16 ) on the one hand and circulation pump ( 12 ; 230 ; 270 ; 280 ; 290 ), on the other hand, are connected to the ring channels ( 4 , 6 ; 202 , 204 ; 222 ; 240 , 242 , 244 , 246 ) at different points. 19. jacket tube reactor ( 2 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 18, characterized in that the respective connection points lie at least approximately on the same jacket lines of the reactor. 20. Jacket reactor ( 50 ) according to claim 18, characterized in that the respective connection points occur pe ripher offset. 21. Jacket reactor ( 50 ) according to claim 20, characterized in that the dislocation in question carries 90 ° or 180 °. 22. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that above the circulation pump ( 12 ; 230 ; 270 ; 280 ; 290 ) and / or the heat exchanger ( 16 ) is an expansion tank ( 104 , 106 ; 142 ; 254 ) for the heat transfer medium. 23. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 22, characterized in that the shaft ( 252 ) of the circulation pump ( 12 ; 230 ; 270 ; 280 ; 290 ) through the expansion tank ( 104 ; 142 ; 254 ) upwards he stretches and the pump drive is arranged above the expansion tank. 24. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 22 or 23, characterized in that in the expansion tank ( 104 , 106 ; 142 ) a degassing line ( 148 ) leads from the inside of the reaction container ( 8 ; 182 , 184 ; 208 ; 226 ). 25. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 24, characterized in that a throttle ( 149 ) is installed in the degassing line ( 148 ). 26. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that the reaction vessel ( 8 ; 182 , 184 ; 208 ; 226 ) of the Flows through the reaction gas mixture from top to bottom or from bottom to top. 27. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that the reaction vessel ( 8 ; 182 , 184 ; 208 ; 226 ) of the From a global perspective, heat transfer medium flows from top to bottom and / or from bottom to top. 28. Jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to one of the preceding claims, characterized in that the circulation pump ( 12 ; 230 ; 270 ; 280 ; 290 ) from above promotes down. 29. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that the circulation pump ( 12 ; 230 ; 270 ; 280 ; 290 ) before and / or behind the pump impeller ( 248 ) has at least one flow guide vane ( 258 , 260 ). 30. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to any one of the preceding claims, characterized in that the circulation pump ( 12 ; 230 ; 270 ; 280 ; 290 ) with a a pre-pressure pump ( 136 , 298 ) which prevents inadmissible cavitation of their intake pressure is combined. 31. Jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 30, characterized in that the admission pressure pump from an additional pump impeller on the shaft ( 252 ) of the circulation pump ( 12 ; 230 , 270 ; 280 ; 290 ). 32. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) according to claim 30, characterized in that the admission pressure pump ( 136 , 298 ) consists of an injector, which is from the outlet side of the circulation pump ( 12 ; 230 ; 270 ; 280 ; 290 ) is fed here and sucks heat transfer medium from an expansion tank ( 104 ; 142 ). 33. jacket tube reactor ( 50 ; 90 ) according to any one of the preceding claims including claims 6 and 11, characterized in that at least the heat carrier outlet-side ring channel ( 4 ), namely at the feed point of the heat exchanger ( 16 ) and bypass ( 22 ) coming partial flow, is divided by a radial vertical partition ( 52 ) and the partial flow concerned be supplied to the two channel ends ( 60 , 62 ) thus created and divided. 34. tubular reactor ( 50 ; 90 ) according to claim 33, characterized in that the dosing means in question consist of at least one control valve ( 58 ) or a pair of throttling members ( 102 ). 35. jacket tube reactor ( 150 ) according to one of the preceding claims and with two or more circulation pumps ( 12 ), distributed over the circumference of the reaction vessel ( 8 ), characterized in that each of the circulation pumps ( 12 ) in the manner specified own heat exchanger ( 16 ) and a separate bypass ( 22 ) are assigned. 36. jacket tube reactor ( 162 ) according to one of claims 1 to 34 and with two or more circulation pumps ( 12 ) distributed over the circumference of the reaction vessel ( 8 ), characterized in that a common heat exchanger ( 16 ) and a common bypass ( 22 ) are connected to the reaction vessel ( 8 ) at points between the connection points of the circulation pumps ( 12 ). 37. jacket tube reactor ( 150 ; 162 ) according to claim 35 or 36, in conjunction with claim 5, characterized in that circulating pumps ( 12 ), heat exchanger ( 16 ) and bypass or bypasses ( 22 ) to the ring channels ( 4 , 6 ; 202 ; 222 ; 240 , 242 , 244 , 246 ) are connected. 38. jacket tube reactor ( 150 ; 162 ) according to claim 37, characterized in that at least one of the ring channels ( 4 , 6 ) in many sections ( 154 , 156 ; 158 , 160 ; 166 , in accordance with the number of circulating pumps ( 12 ) connected thereto) 168 ) is divided. 39. jacket tube reactor ( 162 ) according to claim 38, characterized in that the heat carrier outlet-side ring channel ( 4 ) in circular sector-shaped sections ( 154 , 156 ), the heat carrier-purely step-side ring channel ( 6 ) is divided into overlapping sections ( 166 , 168 ). 40. jacket tube reactor ( 162 ) according to claim 39, characterized in that the overlap is produced by an essentially wen del-shaped partition ( 164 ). 41. jacket tube reactor ( 162 ) according to claim 39, characterized in that the overlap is made by an approximately Z-shaped angled partition with a horizontal central portion ago. 42. jacket tube reactor ( 162 ) according to any one of claims 39 to 41, characterized in that the overlap makes up between 1 and 100%, preferably between 20 and 100% and most suitably between 50 and 100% of the total ring channel length. 43. jacket tube reactor ( 162 ) according to any one of claims 37 to 42 in conjunction with claim 34, characterized in that on the common heat exchanger ( 16 ) and bypass ( 22 ) leading partial flow from the relevant sections ( 166 , 168 ) of the heat carrier inlet side Ring channel ( 6 ) branched off and then supplied to the individual sections ( 154 , 156 ) of the heat-transferring outlet-side ring channel ( 4 ). 44. jacket tube reactor ( 162 ) according to claim 43, characterized in that the individual sections ( 154 , 156 ) of the heat carrier outlet-side ring channel ( 4 ) supplied part is divided in a metered manner. 45. jacket tube reactor ( 180 ) according to one of the preceding claims as a multi-zone reactor with at least two superimposed, separated by a cutting disc or the like. GE separated reactor zones (I, II; 236, 238), characterized in that each reactor zone on the specified manner, a separate circulation pump ( 12 ), a separate heat exchanger ( 16 ) and a separate bypass ( 22 ) are assigned. 46. jacket tube reactor ( 180 ) according to any one of claims 1 to 44 as a multi-zone reactor with at least two superimposed, by a cutting disc or the like. Separated from each other th reactor zones (I, II; 236, 238), characterized in that a plurality of reactor zones a circulation pump ( 12 ), a heat exchanger ( 16 ) and / or a bypass ( 22 ) is common. 47. Multi-zone jacket tube reactor according to claim 46, characterized in that a parallel connection of heat exchanger ( 16 ) and bypass ( 22 ) with a circulation pump ( 12 ) is connected in series and the respective merging points with the heat carrier feeds ( 6 ) of the reactor zones ( I, II) are connected so that the heat exchanger ( 16 ) and the bypass ( 22 ) only one of the reactor zones (II) are connected in parallel. 48. Multi-zone jacket tube reactor ( 180 ) according to one of claims 45 to 47, characterized in that the heat transfer medium through the individual reactor zones (I, II; 236, 238) passes globally in the same or opposite direction. 49. jacket tube reactor ( 200 ) according to one of the preceding claims as a multi-zone reactor with at least two separate reactor zones (I, II), characterized in that two successive reactor zones (I, II) are separated from one another by a flow dividing zone (III) and the from a common circulating pump ( 12 ) conveyed heat transfer medium through the flow distribution zone (III) in the opposite direction into the two adjoining reactor zones (I, II) and the relevant partial flows from there are valve-controlled returned to the pump inlet. 50. Multi-zone jacket tube reactor ( 200 ) according to claim 49, characterized in that the circulation pump ( 12 ) a single heat exchanger ( 16 ) and a single bypass ( 22 ) are switched in parallel. 51. Multi-zone jacket tube reactor ( 200 ) according to claim 50, characterized in that the heat transfer medium stream emerging from the second reactor zone (II) passes through tubes ( 212 ) running inside the reaction vessel ( 208 ) to the heat transfer outlet ( 202 ) of the first reactor zone (I) is supplied. 52. Multi-zone jacket tube reactor ( 180 ; 190 ; 200 ; 234 ) according to one of claims 45-51, characterized in that the height of an individual reactor zone (I, II; 236, 238)) is between 10 and 80%, preferably between 20 and 80%, the total height of all reactor zones. 53. Multi-zone jacket tube reactor ( 180 ; 190 ; 200 ; 234 ) according to one of claims 45 to 52, characterized in that in at least two reactor zones (I, II; 236, 238) different reactions take place. 54. Multi-zone jacket tube reactor ( 180 ; 190 ; 200 ; 234 ) according to one of claims 45 to 53, characterized in that at least one reactor zone (I, II; 236, 238) is designed as a preheating or after-cooling zone for the reaction gas mixture , 55. Multi-zone jacket tube reactor ( 180 ; 190 ; 200 ; 234 ) according to claim 54, characterized in that the reactor zone in question (I, II; 236, 238) either has no filling or an inert material filling in the reaction tubes. 56. Multi-zone jacket tube reactor ( 234 ) according to one of the preceding claims, characterized in that the respective circulation pump ( 230 ; 270 ; 280 ; 290 ) with a cranked inlet and / or outlet ( 262 , 264 ; 272 , 274 ; 282 , 284 ; 292 ) over the adjacent reactor zone ( 238 ; 236 ) is attached to the reaction vessel or the ring channels surrounding it ( 240 , 242 ; 244 , 246 ). 57. tubular reactor ( 220 ) according to any one of the preceding claims, characterized in that it has at least one heat carrier supply and / or removal ( 222 ) on an intermediate level which is valve-controlled with the outlet or inlet of the circulation pump ( 12 ) is connected. 58. jacket tube reactor ( 2 ; 50 ; 90 ; 150 ; 162 ; 180 ; 190 ; 200 ; 220 ; 234 ) for catalytic gas phase reactions and with at least one outwardly branching heat transfer medium circuit, characterized in that at and / or after mind A mixer ( 38 , 40 ) is arranged at least one junction of the branch-related heat transfer medium streams.