EP0452839A1 - Apparatus for steam production by combining oxygen and hydrogen - Google Patents

Abstract

The invention relates to an apparatus for generating steam by combining hydrogen and oxygen. It comprises a combustion chamber for combining hydrogen and oxygen and a downstream injection cooler, in which the steam generated in the combustion chamber and having a very high temperature is brought by injection of feedwater to the parameters suitable for feeding into the steam turbine, with a simultaneous increase in the steam mass flow. To provide an apparatus which allows in a technically simple manner the high temperatures of 3000 DEG C, arising as a result of the oxidation of hydrogen, to be controlled and the resulting steam to be changed with respect to its parameters, especially temperature and pressure, in such a way that it can be fed to a downstream steam turbine, the injection cooler is formed by a double-walled cylinder (1), on whose inside wall (2) a lining of an axially extending tube bundle is located. The feedwater is fed to the tubes (7) of the tube bundle at the end facing the combustion chamber, the other end of the tubes (7) being connected to the annular space (6) of the double-walled cylinder (1). In a part- region, some tubes (7) of the tube bundle form unlined surfaces (11) by means of radial deflections 7a, on which surfaces injection devices (12) for the feedwater are located in the inside wall (2) of the cylinder (1).

Description

The invention relates to a device for generating water vapor by combining hydrogen and oxygen, in particular for the short-term provision of steam capacity to cover peak performance in thermal power plants, with a combustion chamber for combining hydrogen and oxygen and with a downstream injection cooler, in which the in generated in the combustion chamber, a very high temperature steam is brought by injecting feed water to the parameters suitable for feeding into the steam turbine while increasing the steam mass flow, the desuperheater being formed by a double-walled cylinder.

Such devices for generating steam are described in the earlier German patent application P 39 36 806.8. In them, the fuel formed by hydrogen is blown into a combustion head, together with oxygen as an oxidizer, into a combustion chamber adjoining the injection head. Behind the actual combustion chamber, water with the quality of feed water is injected into the steam flow, which on the one hand achieves a reduction in the very high steam temperature and on the other hand increases the steam mass flow. The subject of the older patent application is the creation of optimal combustion conditions in the combustion chamber.

The present invention has for its object to provide a device of the type described in the introduction, with which it is possible in a technically simple manner to control the high temperatures of around 3000 ° C. which arise from the oxidation of hydrogen and the water vapor which arises with regard to its parameters , in particular temperature and pressure, so that the steam can be fed to a downstream steam turbine.

The solution to this problem by the invention is characterized in that a lining made of an axially extending tube bundle is arranged on the inner wall of the cylinder, the tubes of which are fed to the feed water at the end facing the combustion chamber, the other end of the tubes with the annular space of the is connected to the double-walled cylinder, and that some tubes of the tube bundle form part of the length through radial deflections, liner-free surfaces between the continuous tubes, in which are arranged in the inner wall of the cylinder injectors for the feed water, which is by an installation element to the end facing away from the feed water inlet fed feed water of the annulus.

With the proposal of the invention, a steam generator of the generic type consisting of a combustion chamber and an injection cooler is created, which consists of simple components which can be manufactured in a conventional manner and processed with conventional technology, the high temperatures and pressures being safely controlled. The entire inner wall of the double-walled cylinder is cooled intensively, in the area of the lining by the tubes, which also largely prevent heating of the inner wall by radiation, and in the area of the lining-free surfaces by the in in this area feed water exiting through the injection openings. The design according to the invention thus avoids uncontrollable thermal stresses both in the stationary operating state and when starting and stopping, because thin-walled components are used and structural temperature differences within a component are avoided.

The device according to the invention is particularly suitable for the short-term provision of steam capacity for covering peak power in thermal power plants, which can be both conventional steam generators and nuclear power plants.

In a preferred embodiment of the invention, the injection devices are formed by radially oriented pipe sections which are arranged between the continuous pipes and the bends of the remaining pipes in the radial direction behind these pipes in the liner-free surfaces of the inner wall. These tube pieces are equipped at their outlet end with a bottom provided with outlet openings. The outlet end of the pipe sections can be chamfered.

According to a further feature of the invention, the installation element used to guide the feed water in the annular space can be designed as a feed water guide cylinder running in the area of the injection devices and in the area between the injection devices and the front end of the double-walled cylinder. This also results in a simple construction for this component, which ensures that the feed water entering the annular space of the double-walled cylinder from the ends of the pipes is guided past the injectors to the other end of the annular space, so that the inner wall of the double-walled cylinder is reliably cooled over its entire surface by feed water.

The tubes of the tube bundle are made with a very small wall thickness and from a material with high thermal conductivity and a low coefficient of thermal expansion. In one embodiment, circular tubes with a diameter of 6 mm and a wall thickness of 0.3 mm are used in cross section.

The portion of the double-walled cylinder lying between the front end of the double-walled cylinder and the injection openings can be formed at least as part of the combustion chamber. In this way, the combustion chamber used for the oxidation of the hydrogen, in which temperatures of approximately 3000 ° C. prevail, can be constructed at least partially in one piece with the injection cooler according to the invention.

Fig. 1

einen verkürzt dargestellten Längsschnitt durch die Vorrichtung,

Fig. 2

einen Teilschnitt durch den doppelwandigen Zylinder gemäß der Schnittlinie II - II in Fig.1,

Fig. 3

eine vergrößerte Teildarstellung der in Fig. 2 eingekreisten Einzelheit.

An exemplary embodiment of the device according to the invention is shown in the drawing, namely:

Fig. 1

a shortened longitudinal section through the device,

Fig. 2

a partial section through the double-walled cylinder according to section line II - II in Fig.1,

Fig. 3

an enlarged partial view of the detail circled in Fig. 2.

The device intended for the production of water vapor by combining hydrogen and oxygen comprises a double-walled cylinder 1 comprising an inner wall 2, an outer wall 3 and two end walls 4 and 5, through which an annular space 6 is formed which extends over the entire length of the double-walled cylinder 1. A lining of a plurality of tubes 7 is arranged on the inner wall 2.

These tubes 7 form a tube bundle with an axial course. In the exemplary embodiment, the tubes have a circular cross section with an outer diameter of 6 mm and a wall thickness of 0.3 mm. However, tubes with a different cross section, for example a rectangular cross section, can also be used.

The tubes 7 of the tube bundle 1 are supplied with feed water at the end of the cylinder formed by the end wall 4. The feed water supply 8 is indicated by an arrow. The other end of the pipes 7 is connected via pipe bends 9 to the end of the annular space 6 which is closed by the end wall 5. At this end, the double-walled cylinder 1 is provided with an annular flange 10 for suspension or storage.

On a partial length of the longitudinal extension of the tube bundle, some tubes 7 are provided with radial bends 7a, so that there are liner-free surfaces 11 on the inner wall 2 between the tubes 7 of the tube bundle passing through (see FIG. 2). In the embodiment shown in the drawing, every second tube 7 is provided with such a bend 7a. The bends 7a are designed such that these partial lengths of the tubes 7 lie radially behind the adjacent, continuous tube 7.

2 shows that this creates axially extending surfaces 11 between adjacent tubes 7. Injection devices in the form of pipe sections 12 are arranged on these lining-free surfaces 11 of the inner wall 2. Overall, there are several axially extending rows of such radially aligned pipe sections 12 distributed over the circumference of the cylinder 1. In the bottom of these pipe sections 12, outlet openings 12a are formed according to FIG. According to Figure 1, the pipe sections 12 are chamfered.

Feed water is injected into the interior of the cylinder 1 through these outlet openings 12a. The feed water is closed flows in front of the tubes 7 and the entire axial extent of the annular space 6. As a result, not only the tubes 7 but also the inner wall 2 are cooled. In order to also ensure cooling of the part length of the inner wall 2 adjoining the end wall 4, a feed water guide cylinder 13 is arranged in the annular space 6, which extends both over the area of the pipe sections 12 and over the area of the inner wall 2 that extends between the end wall 4 and the pipe sections 12 lies. The feed water guide cylinder 13 thus ensures that the feed water supplied to the annular space 6 via the pipe bends 9 reaches the region of the end wall 4 and is supplied to the pipe sections 12 coming from this end wall 4.

The sectional view in FIG. 1 finally shows that, in the exemplary embodiment, the inner wall 2 of the cylinder 1 is also bent radially outward in the region of the bends 7a. In this way, in conjunction with the tube pieces 12, these bends 7a are guided against lateral displacements; on the other hand it is avoided that uncontrollable thermal stresses occur in the area of the lining-free surfaces 11

An arrow 14 in FIG. 1 indicates that the end of the double-walled cylinder 1 which has the end wall 4 is supplied with water vapor which is formed by combining hydrogen and oxygen. The inlet area of this medium, which is approximately 3000 ° C., accordingly forms at least part of a combustion chamber which is cooled by feed water. This feed water, which is fed through the feed water supply 8 first to the pipes 7 and then to the annular space 6 for cooling, is then injected into the interior of the double-walled cylinder 1 via the outlet openings 12a of the pipe sections 12, which on the one hand causes the parameters, in particular temperature and pressure, of the hot feed water can be brought to values which allow the steam emerging from the cylinder 1 to feed downstream steam turbine; on the other hand, the steam mass flow is increased by the injected feed water, since the quantity of steam supplied to the downstream steam turbine, not shown in the drawing, results from the addition of the two partial quantities which, on the one hand, result from combining hydrogen and oxygen and, on the other hand, from evaporation of the feed water.

The exemplary embodiment shown in the drawing shows that the injection cooler forming at least part of the combustion chamber consists of simple components which can also be produced in a conventional manner and processed using conventional technology. All parts of the construction heated by contact or radiation from the steam at 3000 ° C are reliably cooled, while at the same time ensuring that no uncontrollable thermal stresses arise in the components, both in a stationary operating state and when starting up and shutting down. In this context, it is important that thin-walled components with a constant wall thickness are used, so that structure-related temperature differences within a component are also excluded.

Reference symbol list:

1

cylinder

2nd

Interior wall

2a

deepening

3rd

Outer wall

4th

Front wall

5

Front wall

6

Annulus

7

pipe

7a

Deflection

8th

Feed water supply

9

Elbows

10th

Ring flange

11

liner-free area

12

Pipe piece

12a

Outlet opening

13

Feed water guide cylinder

14

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Claims (5)

Device for generating water vapor by combining hydrogen and oxygen, in particular for the short-term provision of steam capacity to cover peak power in thermal power plants, with a combustion chamber for combining hydrogen and oxygen and with a downstream injection cooler, in which the generated in the combustion chamber, a very high temperature water vapor is brought into the parameters suitable for feeding into the steam turbine by injecting feed water while simultaneously increasing the steam mass flow, the desuperheater being formed by a double-walled cylinder,
characterized,
that on the inner wall (2) of the cylinder (1) a lining made of an axially extending tube bundle is arranged, the tubes (7) of which are fed to the feed water at the end facing the combustion chamber, the other end of the tubes (7) with the annular space (6) of the double-walled cylinder (1), and that some tubes (7) of the tube bundle form liner-free surfaces (11) between the continuous tubes (7) over a partial length by radial bends (7a), in which in the inner wall ( 2) of the cylinder (1) are arranged injectors (12) for the feed water, to which the feed water fed through an installation element (13) to the end of the annular space (6) facing away from the feed water inlet is supplied. Apparatus according to claim 1, characterized in that the injection devices are formed by radially oriented pipe sections (12) which are located between the continuous pipes (7) and those behind these pipes (7) in the radial direction. extending bends (7a) of the remaining tubes (7) in the lining-free surfaces (11) of the inner wall (2) are arranged. Device according to claim 2, characterized in that the pipe pieces (12) are equipped at their outlet end with a bottom provided with outlet openings (12a). Apparatus according to claim 2 or 3, characterized in that the outlet end of the pipe sections (12) is chamfered. Device according to at least one of Claims 1 to 4, characterized in that the built-in element is designed as a feed water guide cylinder (13) running in the area of the injection devices (12) and in the area between the injection devices (12) and the front end of the double-walled cylinder (1) is.

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