DE4241464A1 - Supply of gas turbine exhaust gas as combustion gas to ovens or furnaces - exhaust gas is mixed with air extracted from gas turbine compressor - Google Patents

Abstract

Process for supplying ovens or furnaces (A to F) with oxygen-rich combustion gas in industrial plants containing a gas turbine (1 to 7) has the novelty that air (18) is extracted from the gas turbine compressor (1) and is mixed with the gas turbine exhaust gas (9) which is then supplied as combustion gas to the ovens or furnaces. The air may be heated (19) before being mixed with the exhaust gas. If turbine exhaust gas is not available, fresh air is admitted to the ovens via valves (a to f) and the connections to the gas turbine are closed off preferably by the same valves. USE/ADVANTAGE - Especially for supplying combustion gas to pyrolysis ovens in olefin plants. A simple system is provided by which the cost and reliability of operation of the ovens/furnaces under normal conditions, and when the gas turbine exhaust gas is not available, are improved.

Description

The invention relates to a method for loading furnaces or fireplaces in industrial plants, in particular from Pyrolysis furnaces in olefin plants with oxygen Combustion gas, the combustion gas being the Exhaust gases from the gas turbine and admixed air be used.

From European patent specification 0 122 534, for example a process for operating an olefin plant for the cleavage (Cracking) of hydrocarbons, the hydrocarbons indirectly in cracking or pyrolysis furnaces for olefin production when burning a heating medium with a heat generated by oxygen-containing combustion gas is heated become known. The exhaust gas from a gas turbine Gas turbine system, its essential components Air compressors, gas generators and power turbines are used with air mixes as combustion gas in the pyrolysis furnace for combustion of the heating medium supplied, a through the gas turbine Electric generator is driven. Because the exhaust gases from the gas turbine the oxygen content required in the combustion gas will, in order to cover the lack of oxygen demand, Air supplied to the exhaust gases of the fresh air blower Admixed gas turbine. The oxygen-containing combustion gas is made up of two components: the Exhaust gas from the gas turbine and out via a fresh air blower sucked in air.  

In the publication "Gas turbine integration reduces ethylene plant's energy needs ", John V. Albano and Edward F. Olszewski, Oil & Gas Journal, Feb. 10, 1992, pages 55-60 such a method is also described.

As a result of a failure or a shutdown of the gas turbine or of the gas turbine system to supply the downstream Pyrolysis furnaces are disturbed with combustion gas Olefin plants usually have an emergency system for The pyrolysis furnaces are supplied with combustion gas. The emergency system can consist of the above mentioned fresh air blower is designed so that it at a Failure of the gas turbine can meet the increased air requirement. In Usually, however, for a possible failure of the Gas turbine one or more emergency air blowers in the system provided.

The invention has for its object a method of point out at the beginning, in which in simple Way of supplying the stoves or fireplaces with Combustion gas is ensured. The aim is to equipment expenditure of the plant with regard to the Normal operation, but also with regard to the Reduce emergency operations in the event of a gas turbine failure.

This object is achieved in that air from Air compressor branched off the gas turbine, the exhaust gas from the Gas turbine admixed and the mixture as combustion gas in the downstream stoves or fireplaces are managed.

According to the invention, the required is therefore in normal operation Fresh air not, as in methods according to the prior art, supplied by a separate fresh air blower, but by Air compressor of the gas turbine. The amount of fresh air required is preferred after the first compression stages of the  Air compressor of the gas turbine, i.e. with a relatively low one Pressure, branched off and the turbine exhaust gases at the turbine outlet added.

The method according to the invention thus leads to an essential simplification of fresh air supply to ovens, ins particular of pyrolysis furnaces of an olefin plant, but also of other fireplaces.

The gas from the air compressor can be particularly advantageous turbine branched air before mixing with the exhaust gas of the Gas turbine are heated. This allows the temperature of the Combustion gas for the downstream furnaces can be increased.

In a development of the invention, the ovens are at one Failure of the gas turbine with fresh air as combustion air supplied, the fresh air through air flaps on the ovens into the feed lines to the burners of the furnaces. The air flaps on the ovens open if the Gas turbine automatically and ensure by the Fresh air supply to the ovens is the continuous supply of the required combustion gas. The air flaps are there preferably on the last exhaust gas distribution duct sections to the Stoves attached to the fresh air path to the burners like this as short as possible. An uninterrupted furnace operation remains secured even if the gas turbine fails.

Advantageously, in the event of a failure of the gas turbine If the connections of the supply line of the ver combustion gas for normal operation to the furnaces completed, d. H. the connections of the leads of the invention in Normal operation as a mixture gas used branched air from the air compressor of the gas turbine and the Exhaust gas from the gas turbine to the exhaust gas distribution duct sections through the flaps on the stoves close to the burners interrupted. There are particular advantages if the same flaps the connections of the supply line of the  Lock off the combustion gas to the stoves during normal operation and at the same time as air flaps the fresh air supply to the Open ovens. The air flaps prevent in this case at the same time the supply of residual exhaust gas from the Feeding the combustion gas for normal operation. It can in addition to such flaps with double function even more pure air dampers are used to Supply the furnaces with sufficient combustion air to back up.

The invention is described below on the basis of a comparison the inventive method in one embodiment to a process example according to the prior art explained.

Here shows:

Fig. 1 shows a simplified process scheme according to the prior art and

Fig. 2 shows a simplified process diagram according to the invention.

Equivalents are given the same reference numerals in FIGS. 1 and 2.

In Fig. 1, a gas turbine system with the air compressor 1, the gas generator 4 and the gas turbine 7 is shown. Purified air is supplied to the air compressor 1 via line 2 . The compressed air is fed via line 3 into the gas generator 4 , which is supplied with fuel for gas generation via line 5 . The gas from the gas generator 4 is fed via line 6 into the gas turbine 7 , through which the electric generator 8 and the air compressor 1 are driven.

The exhaust gases from the gas turbine 7 in line 9 are mixed with fresh air in line 11 from a fresh air blower 10 and fed via line 12 into the pyrolysis furnaces A, B, C, D, E and F.

If the gas turbine 7 fails, the switching flap 13 is closed. In this case, additional fresh air to replace the exhaust gases 9 of the gas turbine 7 is fed into the pyrolysis furnaces A to F via the emergency blower 16 via line 17 .

If the furnaces A to F are not in operation, the switching flap 14 is opened so that the exhaust gases 9 of the gas turbine 7 are discharged via the chimney 15 , and the switching flap 13 is closed.

In contrast to FIG. 1, in the process diagram shown in FIG. 2, part of the air fed into the air compressor 1 via line 2 is branched off after the first compression stages of the air compressor 1 via line 18 and mixed with the exhaust gas of the gas turbine 7 in line 9 . The mixture is passed as combustion gas via line 12 into the pyrolysis furnaces A to F. The air branched out of the air compressor 1 from line 18 can additionally, especially if a heat source is present, be heated via a heat exchanger 19 before mixing with the exhaust gases of the gas turbine 7 from line 9 .

In FIG. 2 also shows an inventive emergency system for failure of the gas turbine system and the gas turbine 7 is provided. In normal operation, the air flaps a to f are set so that the combustion gas is fed from line 12 into the furnaces A to F (air flaps a to f in the flap position shown with a solid line). In the event of a failure of the gas turbine system or the gas turbine 7 , the switching flap 13 is closed. In this case, fresh air is fed as combustion gas into the pyrolysis furnaces A to F via the sudden and automatically folded air flaps a to f (air flaps a to f in the flap position shown in dotted lines). At the same time, the switching flaps a to f interrupt the connections from line 12 to furnaces A to F, thus closing furnaces A to F against residual exhaust gas from line 12 and the connecting lines.

Claims (4)

1. A method for charging furnaces or fireplaces in industrial plants equipped with a gas turbine system, in particular pyrolysis furnaces in olefin plants, with oxygen-containing combustion gas, the hot, oxygen-containing exhaust gases of the gas turbine and mixed air being used as the combustion gas, characterized in that air branched off from the air compressor of the gas turbine, mixed with the exhaust gas from the gas turbine and the mixture is fed as combustion gas into the downstream stoves or fireplaces. 2. The method according to claim 1, characterized in that the Air diverted from the air compressor of the gas turbine before Mixing with the exhaust gas from the gas turbine is heated. 3. The method according to any one of claims 1 or 2, characterized characterized in that the furnaces in the event of a failure of the Gas turbine supplied with fresh air as combustion gas the fresh air through air flaps on the ovens is introduced into the ovens. 4. The method according to claim 3, characterized in that by flaps on the furnaces in the event of a gas turbine failure the connections for supplying the combustion gas for normal operation of the ovens is completed.