KR960010081A - Catalyst assembly providing high surface area for nitric acid and / or hydrogen cyanide synthesis - Google Patents

Abstract

The present invention provides a catalyst comprising a plurality of microporous wire mesh sheets arranged to closely overlap one another along a wide surface of the sheet, wherein the wire sheet forms a non-planar cross-section consisting of a plurality of corrugated corrugations. To an assembly. The edge of the catalyst assembly is flat and safely installed in the ammonia converter. The present invention includes not only individual sheets superimposed so as to be adjacent to each other, but also pads composed of a plurality of sheets that combine with each other to form an integrated body. The catalyst assembly of the present invention provides a reduced pressure drop with increased surface area which contributes to increasing the special and useful life and reduces process costs and downtime. Catalyst assemblies can be readily manufactured and installed and can be manufactured in a variety of sizes and shapes to suit the different volumes and requirements of different reactors. The present invention also relates to a method of making a catalyst assembly, as well as a method of treating ammonia using the assembly.

Description

Catalyst assembly providing high surface area for nitric acid and / or hydrogen cyanide synthesis

Since this is an open matter, no full text was included.

2 is a perspective view of a catalyst assembly according to the invention,

3 and 4 are plan views of the catalyst assembly of the present invention made to have circular and hexagonal rims,

5 is a side view of a catalyst assembly according to one embodiment of the present invention.

Claims (24)

It consists of a plurality of wire mesh sheets comprising a catalytic metal having a wide microporous surface, adjacent unprocessed surfaces of these sheets closely stacked on each other, which surfaces are not planar but have a plurality of valleys in most areas. Catalyst assembly for ammonia oxidation which provides increased catalyst surface area with weaker degree of pressure drop. The catalyst assembly of claim 1, wherein each sheet has a flat outer circumference. The catalyst assembly of claim 1, wherein the sheets are joined together along their periphery and the periphery is substantially planar. 4. The catalyst assembly of claim 3, wherein the sheets are joined together along the periphery by heating and / or air pressure. The catalyst assembly of claim 1, wherein the valleys are regularly spaced apart. The catalyst assembly of claim 1, wherein the catalyst assembly has a surface area of about 1.6 to about 1.7 times the surface area of the planar catalyst gauze assembly having the same outer circumference. The catalyst assembly of claim 1, wherein the wire mesh sheets are made of woven metallic gauze. 8. The catalyst assembly of claim 7, wherein the wire mesh sheets are made from a material selected from the group consisting of platinum and alloys thereof. The catalyst assembly of claim 8, wherein the wire mesh sheets contain at least 85% or more platinum. The catalyst assembly of claim 8, wherein the wire mesh sheets are made from an alloy of platinum, rhodium, and optionally palladium. The catalyst assembly of claim 1, further comprising a catalyst support screen having a non-planar surface corresponding to the surface of the wire mesh sheet and positioned below the sheet. The catalyst assembly of claim 1, wherein all sheets are arranged as one unit between two substantially planar outer wire mesh sheets. The catalyst assembly of claim 1, wherein the at least one sheet is provided with a coating to aid in initiation of ammonia oxidation. The catalyst assembly of claim 13, wherein up to 50% of the sheet is continuously coated with the coating starting from the top of the sheet containing the catalyst metal in the assembly. (a) preparing at least one microporous catalytic metal sheet, wherein the sheet has an area greater than the area of the corresponding circumferential planar sheet in dimension in the final circumference of the catalyst assembly; (b) pleating the sheet of step (a) to form a broad non-planar surface; (c) cutting the sheet of step (b) to the dimensions of the final perimeter of the assembly; And (d) flattening the outer periphery of the cutting sheet; a method of making a catalyst assembly providing increased surface area and reduced pressure drop. The method of claim 15, wherein step (b) is performed by crimping the sheet between the corrugated rolls. The method of claim 15 wherein step (d) is carried out by heating and / or pressurization. The method of claim 15, wherein the surface area of the sheet after performing step (b) is about 1.6 to about 1.7 times the surface area of the planar sheet having the same outer circumference. The process according to claim 15, wherein the plurality of sheets are processed according to steps (a) to (c), the sheets are overlapped together in intimately inscribed state with each other, and the outer periphery of these sheets is then simultaneously subjected to step (d). How to process The method of claim 15, wherein the at least one sheet is provided with a coating to assist in initiating the ammonia oxidation reaction. The method of claim 20, wherein up to 50% of the catalytic metal sheet is continuously coated with the coating starting from the top of the catalytic metal sheet in the assembly. A process for the reaction of ammonia to produce a reaction byproduct selected from nitric acid and hydrogen cyanide consisting of passing ammonia through a reactor comprising a catalyst for converting ammonia to a byproduct, comprising a catalytic metal having a wide microporous surface. Consisting of a plurality of wire mesh sheets, adjacent microporous surfaces of these sheets closely stacked on each other, with a weaker degree of pressure drop in which the surfaces of the sheet have a plurality of valleys rather than being flat in most areas; An improvement method characterized by passing ammonia through a catalyst assembly providing together increased catalyst surface area The method of claim 22, wherein each sheet has a flat outer circumference. 23. The method of claim 22, wherein the sheets are joined together along their periphery and the periphery is substantially planar. ※ Note: The disclosure is based on the initial application.