TH129731A - A method for producing unsaturated acids in a fix-bed catalytic oxidation reactor with a heat-raising control system. - Google Patents

Abstract

------24/04/2019------(OCR) Page 1 of 1 Summary of Invention This invention provides for the production of unsaturated acids from unsaturated aldehydes by accelerated partial oxygenation in a fixed platform in a shell and tube heat exchanger reactor, including a shell and tube heat exchanger reactor for use in this process. In the present invention, a secondary reaction zone, which primarily produces unsaturated acids by catalytic vapor phase oxygenation of a gaseous mixture containing unsaturated aldehydes produced in the primary reaction zone with molecular oxygen, is divided into two or more cladding spaces by at least one partition. Each partitioned cladding space is filled with a heat transfer medium, and the heat transfer medium in each cladding space is maintained at a constant temperature, or a temperature difference of 0-5 °C. In addition, to protect the catalyst layer from highly exothermic reactions, the process is carried out at a limited temperature difference between the hot spot temperature and the heat transfer medium temperature. In addition, To facilitate heat generation at the partition site, an inhibitor layer is positioned therein. The improved thermal control system for the reactor arranged according to the present invention can ensure the thermal stability of the catalyst layer, thereby reducing the by-product content and increasing the yield of the final product. ------------ DC60 (02/03/48) The present invention provides a process for producing unsaturated acids from unsaturated aldehydes by accelerated partial oxygenation in a fixed platform in a shell-and-tube heat exchanger reactor, including a shell-and-tube heat exchanger reactor for use in this process. In the present invention, a secondary reaction zone, which primarily produces unsaturated acids by catalytic vapor phase oxygenation of a gaseous mixture containing unsaturated aldehydes produced in the primary reaction zone with molecular oxygen, is divided into two or more cladding areas by at least one partition. Each partitioned cladding area is filled with a heat transfer medium. And the heat transfer medium in the area inside each cladding is maintained at a constant temperature or a temperature difference of 0-5 °C. In addition, to protect the catalyst layer from the highly exothermic reaction, the process is carried out in a limited temperature difference between the hot spot temperature and the heat transfer medium temperature. Furthermore, to allow heat generation to be easily eliminated at the partition location, an inhibitor layer is positioned therein. The improved thermal control system for the reactor arranged according to the present invention can ensure the thermal stability of the catalyst layer, thereby reducing the amount of by-products and increasing the yield of the final product.

Claims (3)

Claims (All) Which Will Not Appear on This Advertisement Page :------01/02/2018------(OCR) Page 1 of 3 Claim 1. A process for producing unsaturated acids from unsaturated aldehydes by accelerated partial oxidation reactions in a stationary platform in a shell and tube heat exchanger reactor. The process comprises one or more catalyst tubes, wherein each catalyst tube includes a reaction zone to produce the unsaturated acid, the modification being such that the reaction zone is divided into two or more cladding areas by at least one partition, with each partitioned cladding area filled with a heat transfer medium, the heat transfer medium being maintained at a constant or varying temperature. 1. The process of claim 1, wherein the temperature difference between a heat transfer medium added to the area inside the cladding is between 0°C and 50°C. 2. The process of claim 1, wherein the temperature difference between a heat transfer medium added to the area inside the cladding is between 0°C and 50°C. 3. The process of claim 1, wherein the temperature difference between a heat transfer medium added to the area inside the cladding is between 0°C and 50°C. 4. The process of claim 1, wherein the cladding is positioned at the location of the maximum temperature produced in the reaction zone. Page 2 of 3. 5. The process of claim 4, wherein the maximum temperature occurs in the reactor inlet, the reaction zone face, 6. The process as stated in claim 1, wherein the volume ratio of inactive material to catalyst material in the inhibitor layer is 20-100%. 7. The process as stated in claim 1, wherein the temperature of the heat transfer medium added to the space inside each cladding can be controlled independently. 8. The process as stated in claim 1, wherein the time velocity of the unsaturated aldehyde introduced into the reactor inlet is in the range of 50-130 hr\'1. 9. A shell and tube heat exchanger reactor which can be used for the production of unsaturated acids from olefins by accelerated partial oxidation reactions in a stationary platform. The reactor comprises one or more catalyst tubes, wherein each catalyst tube includes a A first-layer reaction zone which mainly produces unsaturated aldehydes, a second-layer reaction zone which mainly produces unsaturated acids, or a dual-layer reaction zone. The modification is such that the second-layer reaction zone is divided into two or more cladding areas by at least one partition, wherein each partition area is filled with a heat transfer medium and the heat transfer medium is maintained at a constant temperature or temperature difference of 0-5 °C, whereby a single inactive material inhibitor or a mixture of inactive materials and a catalyst are positioned inside the catalyst tube corresponding to the partition arrangement and page 3 of three, whereby the height of the added inhibitor layer is 120% to 150% of the partition thickness. ------------ 1. In the process of producing unsaturated acids from unsaturated aldehydes by combining with Partially accelerated oxygenation in a fixed platform in a shell and tube heat exchanger reactor. The reactor shall consist of one or more catalyst tubes, where each catalyst tube shall include a reaction zone to produce unsaturated acids. The modification is such that the reaction zone is divided into two or more shell areas by at least one partition, with each partition filled with a heat transfer medium, the heat transfer medium being maintained at a constant temperature or a temperature difference of 0-5 °C. When the shell areas divided by partitions in the reaction zones are named, for example, zone 1, zone 2, zone 3... and zone N in the axial direction, it is found that Th1- Tsa/11 < 130 °C and Thn-Tsa/tn < 110 °C, where N is an integer equal to 2 or more, Th1 is the maximum temperature of the reaction mixture in the corresponding catalyst layer. with the inner shell area one, ThN is the maximum temperature of the reaction mixture in the catalyst layer corresponding to the inner shell area Nth, Tsalt1 is the temperature of the heat transfer medium filled in the inner shell area one, and TsaltN is the temperature of the heat transfer medium filled in the inner shell area Nth. 2. In the process of producing unsaturated acids from unsaturated aldehydes by partial oxygen catalyzed reaction in a fixed platform in a shell and tube heat exchanger reactor, the reactor consists of one or more catalyst tubes, where the catalyst tubes include a reaction zone to produce the unsaturated acid. The modification is such that the reaction zone is divided into two or more shell areas by at least one partition, with each partitioned shell area filled with a heat transfer medium, the heat transfer medium being maintained at a constant or differential temperature. Temperature conditions are 0-5 °C, where an inhibitor layer made of either an inactive material alone or a mixture of an inactive material and a catalyst material is positioned inside the catalyst tube corresponding to the placement of the 3 partitions. The process of claim 1 or 2, wherein the temperature difference between a heat transfer medium introduced into the enclosure space next to it is in the range between 0°C and 50°C. 5. The process of claim 1 or 2, wherein the partitions are arranged so as to cover at least one temperature peak. 6. The process of claim 5, wherein the temperature peak occurs at the reactor inlet, the front of the reaction zone, or the boundary between adjacent catalyst layers of different activity. 7. The process of claim 1, wherein the inhibitor layer made of a single inactive material, or a mixture of an inactive material and a catalyst material is Placed in a position within the catalyst tube corresponding to the placement of the separator 8. The process as stated in claims 2 or 7, wherein the volume ratio of inactive material to catalyst material in the inhibitor layer is 20-100%. 9. The process as stated in claims 2 or 7, wherein the height of the added inhibitor layer is 20-500% of the thickness of the separator 1 0. The process as stated in claims 1 or 2, wherein the temperature of the heat transfer medium added to each enclosure area can be controlled independently 1 1. The process as described in claim 1 or 2, wherein the time velocity of the unsaturated aldehyde introduced into the reactor inlet is in the range 50-130 hr -1 1. 2. In a shell and tube heat exchanger reactor, which can be used in the production of unsaturated acids from olefins by accelerated partial oxygenation in a fixed platform, the reactor consists of one or more catalyst tubes, where each catalyst tube includes a primary reaction zone that mainly produces unsaturated aldehydes, a secondary reaction zone that mainly produces unsaturated acids, or both. The modification is such that the secondary reaction zone is divided into two or more shell spaces by at least one partition, where each partition space is filled with a heat transfer medium, and the heat transfer medium in the shell space is filled with a heat transfer medium. Each cladding is maintained at a constant temperature or a temperature difference of 0-5 °C, and when the cladding area divided by the partition in the second reaction zone is named as, for example, zone 1, zone 2, zone 3... and zone N in the axial direction, it is found that Th1-Tsa/11 <130 °C and Thn - Tsa/tn < 110 °C, where N is an integer equal to 2 or more, Th1 is the maximum temperature of the catalyst reaction mixture corresponding to the first cladding area, Thn is the maximum temperature of the catalyst reaction mixture corresponding to the Nth cladding area, Tsalt1 is the temperature of the heat transfer medium added to the first cladding area, and TsaltN is the temperature of the heat transfer medium added to the Nth cladding area 1. 3. In a shell and tube heat exchanger reactor, which can be used to produce unsaturated acids from olefins by accelerated partial oxygenation in a fixed platform, the reactor consists of one or more catalyst tubes, where each catalyst tube includes a primary reaction zone that mainly produces unsaturated aldehydes, a secondary reaction zone that mainly produces unsaturated acids, or both reaction zones. The modification is such that the secondary reaction zone is divided into two or more shell spaces by at least one partition, where each partition space is filled with a heat transfer medium and the heat transfer medium is maintained at a constant temperature or a temperature difference of 0–5 C, whereby an inhibitor layer made of either an inactive material alone or a mixture of an inactive material and a catalyst is positioned within the catalyst tubes that corresponds to the position of the partitions.