Heat-recovery boiler

Abstract

The invention relates to a heat-recovery boiler (3) consisting of a tube bundle heat exchanger (7) which is incorporated into a pressure vessel (2) downstream of a gasification device. Displacement bodies (9) are inserted into pipes which are flowed around by hot process gas. According to said invention, in order to avoid corrosion problems like metal dusting, said displacement bodies (9) are made of graphite.

Description

The present invention relates to a heat-recovery boiler comprising a tube bundle heat exchanger permanently incorporated into a pressure vessel downstream from a gasification device, a displacement body, which extends over at least a part of the length of the pipe, being inserted centrally and coaxially into each of the pipes which hot process gas flows around to form an annular space with the interior of the pipe.

In the chemical industry, heat-recovery boilers are widely employed to exploit the waste heat from upstream processes for steam generation, in that hot process gases, typically having a temperature from 800 to 1300° C., are cooled and simultaneously high-pressure steam is generated. In this case, deposits may form on the inner surface of the pipes, which significantly impair the heat transfer between the process gas and the coolant liquid flowing around the pipes because of their comparatively low thermal conductivity. The formation of such deposits is to be attributed either to materials existing in the process gases or to those materials which first form in the pipes upon cooling of the process gases. The process of the occurrence of such disadvantageous deposits is referred to in the professional world as “fouling”. In order to limit fouling in the pipes, providing the process gases with a sufficient flow velocity is known. However, since the flow velocity may not be elevated unlimitedly for reasons of a pressure loss which rises therewith, displacement bodies are inserted into the cooling pipes in a known way, which are to either elevate the turbulence of the process gas flow or even elevate its flow velocity locally, through which the deposits of solids are reduced and simultaneously the heat transfer is improved. The displacement bodies, which typically comprise metal and are preferably implemented as closed insertion tubes, are disadvantageously subject, particularly if the process gases have high concentrations of carbon monoxide, to a significant corrosive attack, referred to as “metal dusting”, in a temperature range from 400 to 850° C., preferably 450 to 750° C. Metal dusting is based on the enrichment of the matrix of a metallic material in the superficial region with carbon, carbide compounds first arising and, upon further saturation, elementary carbon being precipitated. The material structure is destroyed by the precipitation of the carbon, so that it erodes. A requirement for the erosion is the presence of a potential for carbon formation. This potential may be defined by the following reaction equations in the components of a gas mixture obtained through gasification of carbon: CO+H₂C+H₂O(CO reaction) 2CO C+CO₂(Boudouard reaction)

The associated equilibrium temperature may be determined for each of the two reactions from the composition of the gas generated by the gasification. Since both reactions run exothermically, a potential for producing carbon exists if the gas falls below at least one of these temperatures as it is cooled. Whether metal dusting actually occurs is decisively a function of the associated kinetics, whose influencing variables are determined by the local temperature and the material. The temperature limit, below which metal dusting no longer occurs for reasons of kinetics, may be viewed as relatively well-established on the basis of experience, however, it is still largely open how suitable different metallic materials are for use above this temperature limit. In principle, all iron and nickel alloys are susceptible to metal dusting, however, a more or less strong occurrence of the metal dusting occurs as a function of the further components determining the mechanical-technological properties of alloys. Up to this point, the development of a material resistant to metal dusting has not been successful, nor is there a sufficiently established theory about the detailed procedures during metal dusting.

In general, metal dusting may be avoided if the displacement bodies are only subjected to process gases whose temperatures lie above or below the critical temperature range of 400 to 850° C. In the heat-recovery boiler, the pipes which the hot process gases flow through are cooled to temperatures lying significantly below 400° C. by the coolant liquid surrounding them and the vaporization reaction occurring. Since, however, the use of displacement bodies in the critical temperature range of 400 to 850° C. may not be avoided under all circumstances, it is necessary to consider the risk of metal dusting when selecting the material for the displacement body.

It is the object of the present invention, in the initially described heat-recovery boiler, to provide a displacement body resistant to a corrosive attack by metal dusting which is insertable into the pipes of the tube bundle heat exchanger.

This object is achieved according to claim 1 in that the displacement body comprises graphite.

In order to avoid oscillation of the displacement body in the pipes, centering elements are attached to the periphery of the displacement body, preferably materially bonded to the displacement body.

Advantageous implementations of the displacement bodies are specified in claims 3 through 8.

According to the present invention, the displacement bodies are inserted from the outlet side of the process gases into the pipes and extend over at least 30% of the pipe length.

The displacement bodies are expediently made of multiple sections, which are connected via mechanical means made of carbon, such as threaded pins or the like.

The present invention is described in the following in greater detail and for exemplary purposes.

By reacting natural gas with steam and oxygen at a temperature of 970° C., a gas mixture is generated which is composed of 0.1 volume-percent N₂, 6.0 volume-percent CO₂, 14.5 volume-percent CO, 47.3 volume-percent H₂, 0.7 volume-percent CH₄, and 31.4 volume-percent H₂O. The gas mixture supplied to the cracked gas boiler has a pressure of 30 bar and an effective temperature of 9700C. An equilibrium temperature of 788° C. for the CO reduction and of 820° C. for the Boudouard reaction result from the composition of the gas mixture. This means that when the temperature falls below 820° C., a potential for metal dusting exists. In the tube bundle heat exchanger positioned in the cracked gas boiler, which is referred to as a heat-recovery boiler, the gas mixture is therefore cooled to a temperature of approximately 450° C. The gas mixture contains small quantities of components which produce solid or liquid compounds with the CO₂ upon cooling in the heat-recovery boiler as a function of the temperature. Such components are typically alkaline compounds which are introduced, for example, with the natural gas, steam, and/or oxygen or are dissolved from ceramic masses existing in the reaction system, such as the reactor lining or catalysts. Above all, compounds containing sodium and potassium form solid carbonates upon cooling, which at least partially form deposits on the heat exchanger surfaces and therefore worsen the heat exchange, with the result that the process gas temperature rises to a temperature of approximately 500° C. at the outlet of the heat-recovery vessel. Since such a temperature is harmful to the process unit downstream from the heat-recovery boiler, a closed pipe comprising a nickel-chromium alloy of the type Incone® 601, which has the highest resistance to metal dusting currently known, is inserted into each of the cooling pipes as a displacement body while forming an annular space with the interior of the cooling pipe, through which the free cross-section of the cooling pipe is narrowed and the flow velocity of the process gases is elevated, so that the outlet temperature of the process gases is reduced to approximately 450° C.

However, it is a significant disadvantage that the displacement bodies partially dissolve after a relatively short service life of only a few weeks because of corrosion and thus significant quantities of rust-like solid fall into the condensate of the gas generation facility. The form of the corrosion occurrence and the formation of carbon decisively indicate a material attack by metal dusting. In addition, the nickel released upon corrosion results in damage to catalysts, which may possibly be positioned in the process unit downstream from the heat-recovery boiler.

To elevate the resistance, the displacement body comprising Inconel® 601 was additionally coated with a 1.5 mm thick layer made of zirconium silicate as an experiment. As a result, this displacement body was subject to a comparatively even more significant corrosive attack by metal dusting than was the case with the uncoated displacement body.

In contrast, the displacement bodies comprising graphite used according to the present invention have no damage even after a relatively long operating time of more than a year.

Displacement bodies comprising the material Inconel® 601, which were largely destroyed by metal dusting, are illustrated in the photo shown in FIG. 1.

The diagram shown in FIG. 2 shows the course of the corrosion attack by metal dusting along a 3000 mm long displacement body made of the materials Inconel® 601 (dot-dash line), Inconel® 601 coated with zirconium silicate (dashed line), and graphite (solid line). It may be seen that the corrosive attack on the displacement bodies made of the materials Inconel® 601 and Inconel® 601 coated with zirconium silicate is largest in the zones which have the highest temperatures. Accordingly, the corrosive attack falls to <0.5 mm up to the end of the displacement bodies. The displacement bodies comprising graphite show no changes.

The present invention will be explained in greater detail for exemplary purposes by FIG. 3 through FIG. 6.

FIG. 3 shows a partial longitudinal section through a cracked gas boiler in the region of the heat-recovery boiler having displacement bodies made of graphite inserted into its cooling pipes

FIG. 4 shows an enlarged illustration of the detail X of FIG. 1

FIG. 5 shows a cross-section along the section line D-D of FIG. 4

FIG. 6 shows a cross-section along the section line E-E of FIG. 4

By reacting natural gas with steam and oxygen, a gas mixture having a temperature of 970° C. and essentially comprising H₂, CO, CO₂, H₂O, and CH₄ is generated, which is released via the intake chamber (1) end of the cracked gas boiler (2) to the heat-recovery boiler (3). The heat-recovery boiler (3) contains fixed floor pipes (4, 5) at the gas entry and gas outlet sides, into whose holes (6) the ends of the 3000 mm long cooling pipes (7) are welded. The gas mixture exiting out of the heat-recovery boiler (3) leaves the cracked gas boiler (2) via the outlet chamber (8). A displacement body (9) made of graphite, which is hexagonal in cross-section, is inserted concentrically into each of the cooling pipes (7) to form an annular space (10) with the interior of the cooling pipe (7). Centering elements (11), which are triangular in cross-section, are attached to the lateral surface of the displacement body (9) along a spiral line with the tip resting on the interior of the cooling pipe (7). The displacement bodies (9) have a length of 3000 mm and are inserted into the cooling pipes (7) from the side of the gas outlet, a tubular holder (12) being screwed onto each of the end pieces of the displacement bodies (9) projecting past the floor pipes (5) on the gas outlet side. The outlet chamber (8) of the cracked gas boiler (2) is lined with a ceramic layer (13). The displacement bodies (9) each comprise individual sections (14, 15), which are connected to one another via carbon threaded pins (16).

Claims

1. A heat-recovery boiler (3), which comprises a tube bundle heat exchanger permanently installed in a pressurized container (2) and is downstream from a gasification device, a displacement body (9) extending over at least a part of the length of the pipe being inserted centrally and coaxially into each of the pipes (7), which the hot process gases flow through, to form an annular space (10) with the interior of the pipe, characterized in that the displacement body (9) comprises graphite.

2. A heat-recover boiler according to claim 1, characterized by centering elements (11) which are located around the periphery of the displacement body (9) and are preferably materially bonded to the displacement body.

3. The heat-recovery boiler according to claim 1, characterized by centering elements (11) attached running radially in multiple cross-sectional planes of the displacement body (9), a passage which is a circular section in cross-section existing between each two neighboring centering elements.

4. The heat-recovery boiler according to claim 1, characterized in that the centering elements (11) are positioned on a line running diagonally or in a spiral to the axis of the cooling pipe (7).

5. The heat-recovery boiler according to claim 1, characterized in that the displacement body (7) has the cross-section of a circle.

6. The heat-recovery boiler according to claim 1, characterized in that the displacement body (7) has the cross-section of a regular polygon, preferably a hexagon.

7. The heat-recovery boiler according to claim 6, characterized by centering elements (11) which are equilateral triangles in cross-section, the length of the base of the centering elements corresponding to the length of the corresponding side of the polygon.

8. The heat-recovery vessel according to claim 6, characterized by centering elements (11) which are equilateral trapezoids in cross-section, the length of the base of the centering elements corresponding to the length of the corresponding side of the polygon.

9. The heat-recovery vessel according to claim 1, characterized in that the displacement bodies (9) are inserted into the pipes (7) from the outlet side of the process gases and extend over at least 30% of the pipe length.

10. The heat-recovery vessel according to claim 1, characterized in that the displacement bodies (9) are each assembled from multiple sections connected via mechanical means comprising carbon, such as threaded pins or the like.