GB2222533A - Combined tubular primary and secondary reformer - Google Patents

Abstract

A tubular reformer the first part of which is used for reforming of a pressurised steam/hydrocarbon mixture, and in the second part of which is oxidant is introduced directly into the tube, the oxidant then continues the catalytic reforming of the gas in the tube by virtue of the heat released by partial oxidation of part of the gas; the hot reformed gas leaving the tube is then used to heat the reactants inside the tube. <IMAGE>

Description

DESIGN FOR A COMBINED TUBULAR PRIMARY AND SECONDARY REFORMER This invention is a combined tubular primary and secondary reformer in which heat from the oxidation of part of the feedstock is used to partially preheat and reform all or part of a hydrocarbon and steam mixture fed to the reformer.

There now follows a description of one embodiment of the invention.

Steam and hydrocarbon are preheated externally to the reformer. The hot gas then flows from the top head of the reformer down through an annul us inside a tube the annul us being filled with an appropriate commercially available steam/hydrocarbon reforming catalyst-generally nickel supported on a refractory material. The ratio of steam to hydrocarbon is in the molar range 1.0:1 to 4.5:1, more likely in the range 2.0 - 2.5:1. At the entry to the tube it is at a temperature of between 350 and 600 C more likely 500 - 600 C.

As the gas flows down the tube it is heated by hot reformed gas flowing outside the tube and is partly reformed. Some distance down the tube the catalyst is changed to a combined combustion and reforming catalyst. Shortly after this change an inner pipe discharges oxidant into the catalyst-filled annul us through a series of holes. As the oxidant meets the partially reformed gas partial oxidation takes place resulting in heat release and further reforming.

At the exit of the tube reforming is complete and the gas leaves the tube at a temperature between 600 and 1500 C more likely in the range 800 to 1000 C.

The hot gas then flows upwards around the outside of the tube. The base of the tube, in the region of the combined combustion and reforming catalyst, may be insulated to maintain the temperature of the gas for the reforming sector. The reformed gas leaves the reformer close to the inlet gas tubesheet with a temperature within 150 C of the incoming hydrocarbon and more likely within 100 C.

It is possible to add further partially reformed gas at the base of the reformer. This will mix with the gas from the tubes and the heat from both streams can then be exchanged into the gas flowing in the tube-thus reducing on the quantity of oxidant required.

The oxidant is an oxygen-containing gas. Other compounds which may be present are nitrogen, steam and carbon dioxide. The operating pressure of the combined reformer is not limited but would usually be in the range 5 to 70 bar. More usually operation is likely to be in the range 25 - 55 bar. Since the differential pressure across the tube wall is low, the operating pressure has only a small effect on the mechanical design.

One embodiment of the mechanical design is shown in diagram 1.

Reformer tubes, in the size range 75 to 150 mm inside diameter, are connected at the top to a tube sheet and then fall vertically over a length of eg 10M to 20M. The tubes are arranged on a close pitch so as to increase the external heat transfer coefficient. The tube bundle is located in a refractory lined vessel which is either detachable at the tubesheet or at a flange lower down.

Above the tubesheet is an array of oxidant distributors arranged to allow catalyst loading and unloading. From the distributors the oxidant is led down the centre of the reforming tube in a small bore oxidant tube typically 15 - 40 mm OD. The top portion of the oxidant tube may be made of stainless steel containing less than 20% weight nickel. The lower portion of the oxidant tube, ie in the combustion region, may be made of either a high temperature nickel/chrome alloy, or a non metallic material such as silicon nitride. The catalyst support grid may also be made of non metallic material.

The reformer tube may be made of alloy material containing less than 20% nickel by weight for most applications. For very high temperatures at the outlet from the tube either a very high temperature alloy or a non metallic material like silicon nitride may be employed.

Example.

The following example is for the production of methanol synthesis gas.

For a reformer of between 6 to 10 tubes to produce ca 72 tonnes/day of methanol: Feed to tubes 100 kgmol/hr Methane and 250 kgmol/hr steam at 550 C and 33 bar Oxidant 48 kgmol/hr oxygen and 48 kgmol/hr steam at 220 C and 33 bar The product gas leaves the reactor at 650 C and 30 bar. The gas condition at the exit of the two catalyst stages are as follows: : Units Exit Exit Combustion Reforming Reforming Catalyst Catalyst Hydrogen kgmol/hr 93.9 236.6 Carbon monoxide kgmol/hr 4.4 56.0 Carbon dioxide kgmol/hr 20.2 , 41.1 Methane kgmol/hr 75.4 2.8 Steam kgmol/hr 205.2 255.7 Total kgmol/hr 399.1 592.2 Temperature C 635 937 Heat transferred to tube 1.6 Gcal/hr The invention is thus a tubular reformer the first part of which is used for reforming of a pressurised steam/hydrocarbon mixture, and in the second part of which an oxidant is introduced directly into the tube, the oxidant then continues the catalytic reforming of the gas in the tube by virtue of the heat released by partial oxidation of part of the gas; the hot reformed gas leaving the tube is then used to heat the reactants inside the tube.

Claims (1)

1. COMBINED TUBULAR Claim 1 A tubular reformer the first part of which is used for reforming of a pressurised steam/hydrocarbon mixture, and in the second part of which oxidant is introduced directly into the tube, the oxidant then continues the catalytic reforming of the gas in the tube by virtue of the heat released by partial oxidation of part of the gas; the hot reformed gas leaving the tube is then used to heat the reactants inside the tube.

   Claim 2 A reformer as claimed in claim 1 wherein the gas leaving the tube is mixed with additional hot gas which has been reformed elsewhere.

   Claim 3 A reformer as claimed in claim 1 or 2 where a metal, containing less than 20% nickel (by weight), is used for the reforming tube, and the oxidant tube above the point where the oxidant flows through the holes in the oxidant tube.