FIXED BED REACTOR BASED ON THE PRINCIPLE OF THERMOELECTRIC FOR IN-SITU HEAT REMOVAL AND IN-SITU TEMPERATURE MEASUREMENT OF STRONG EXOTHERMIC REACTIONS

Abstract

A fixed bed reactor based on the principle of thermoelectric to achieve in-situ heat removal and in-situ temperature measurement for strong exothermic reactions involves the field of fixed bed devices for heat reuse of exothermic reactions. Specifically, it relates to the field of fixed bed devices based on the principle of thermoelectric for timely heat removal of strong exothermic reactions, and can also measure and monitor the temperature and heat of exothermic reactions from multiple angles, enhancing the heat transfer of the catalytic bed layer, effectively eliminating or reducing the generation of reaction hotspots, and avoiding catalyst deactivation. The utility model comprises a fixed bed reaction tube, and the top of the fixed bed reaction tube is equipped with an infrared temperature measurement system, a potential detection system, and an electric energy collection system.

Claims

1. A fixed bed reactor suitable for in-situ heat removal and in-situ temperature measurement in gas-phase exothermic reactions, comprising a heating jacket and a fixed bed reaction tube, wherein the heating jacket is installed outside the fixed bed reaction tube, a catalyst bed is installed inside the fixed bed reaction tube, two ends of the fixed bed reaction tube are respectively equipped with inlet and outlet ports, a thermocouple is installed inside the fixed bed reaction tube, with one end extending to the catalyst bed and the other end extending outside the fixed bed reaction tube, and the fixed bed reactor further comprises at least one of an electrical signal detection system, an electric energy storage system, and an infrared temperature measurement system.

2. The fixed bed reactor according to claim 1, wherein the infrared temperature measurement system and the electrical energy storage system are installed at a top of the fixed bed reaction tube.

3. The fixed bed reactor according to claim 2, wherein the top of the fixed bed reaction tube is made of germanium glass.

4. The fixed bed reactor according to claim 1, wherein the electric energy storage system comprises rechargeable batteries, potential difference meters, external catalyst filling boxes, and external catalysts, the rechargeable battery, the potentiometer, the external catalyst filling box, and the catalyst bed are connected to form a closed circuit.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] FIG. 1 is a schematic diagram of the fixed bed reactor and infrared temperature measurement system of the present application.

[0013] FIG. 2 is a schematic diagram of the fixed bed reactor and electrical signal detection and storage system of the present application.

[0014] FIG. 3 shows the catalyst loading and support frame of the fixed bed reactor of the present application.

[0015] FIG. 4 is a front view of the catalyst in the fixed bed reactor of the present application.

[0016] FIG. 5 is a top view of the catalyst in the fixed bed reactor of the present application.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0017] The following provides a further detailed explanation of the novel technical solution of the present application, but it is not intended to be a limitation of the present application.

[0018] A fixed bed reactor suitable for thermoelectric to achieve in-situ heat removal of strong exothermic reactions comprises a fixed bed reaction tube, and an infrared temperature measurement system at the top of the fixed bed reaction tube. There are inlet and outlet ports on the side of the fixed bed reaction tube. The fixed bed reaction tube is equipped with a thermocouple inlet. A catalyst bed 4 is installed inside the reaction tube, which is filled with catalyst. A heating jacket 3 is installed outside the fixed bed reaction tube 3, and a thermocouple is installed below the fixed bed reaction tube. The electrical signal detection and storage system includes a potential difference meter 8, a rechargeable battery 9, an external catalyst filling box 10, and an external catalyst 11.

[0019] Temperature measurement is carried out at the top of the fixed bed reaction tube, with an inlet on the side to ensure the temperature of the catalytic bed layer.

EXAMPLE 1

[0020] A fixed bed reactor suitable for in-situ heat removal and in-situ temperature measurement in gas-phase exothermic reactions, as shown in FIG. 1, comprising a heating jacket and a fixed bed reaction tube. The fixed bed reaction tube 3 is inserted into the heating jacket 2. The fixed bed reaction tube is equipped with a catalyst bed layer 4, which is a composite material of acetylene selective hydrogenation to ethylene catalyst and thermoelectric material. The upper and lower ends of the catalyst bed layer are equipped with terminal posts for connecting wires. The fixed bed reaction tube is equipped with inlet 5 and outlet 6 at both ends, with both inlet and outlet located on the side. The top material of fixed bed reaction tube 3 is replaceable. There is a thermocouple 7 inside the tube, with one end in contact with the catalyst bed and the other end extending outside the fixed bed reaction tube.

EXAMPLE 2

[0021] As shown in FIG. 2, it is an electrical signal detection and storage system. The electrical signal detection and storage system includes a potential difference meter 8, a rechargeable battery 9, an external catalyst filling box 10, and an external catalyst 11. As mentioned above, the catalyst bed is equipped with terminal posts, which connect the catalyst, potentiometer, rechargeable battery, and external catalyst in a series circuit using wires. Based on the fixed bed reaction tube, catalyst bed 4 releases heat during the selective hydrogenation of acetylene, resulting in a temperature difference between catalyst 4 and external catalyst 11. According to the principle of thermoelectric, the thermoelectric material releases electrons through the entire series circuit and stores them in the rechargeable battery 9. By using a potential difference meter 8 to detect the intensity of electrical signals, temperature measurement can be achieved.

EXAMPLE 3

[0022] As shown in FIG. 3, it is the catalyst loading and support frame. The catalyst support frame includes conductive aluminum material 12. Joint fastener (insulator) 13. Conductive aluminum rod 14. Upper terminal nut 16. Upper terminal post 17. Lower terminal post 18. Bottom terminal nut 19. Fix the upper and lower conductive aluminum materials with the catalyst module in the fixed bed reaction tube by using fastener 13. As mentioned earlier, one end of the conductive aluminum rod is connected to the upper conductive aluminum material, and the other end extends to the lower end of the catalyst bed and is connected to the upper terminal nut 16 and the upper terminal for connection to the series circuit.

EXAMPLE 4

[0023] As shown in FIGS. 4 and 5, the schematic diagram of the catalyst. The catalyst is honeycomb shaped, and three additional holes for fastener 13 and conductive aluminum rod 14 are designed. The catalysts for selective hydrogenation of acetylene are Pd based, Ni based, and Cu based catalysts, and the thermoelectric material is the thermoelectric material bismuth telluride. The purchased acetylene selective hydrogenation catalyst is physically mixed with thermoelectric materials to form a composite material as a catalyst, which has hydrogenation performance for the reaction while removing the heat of the in-situ exothermic reaction.