EP2129966A2

EP2129966A2 - Porous hydrogen burner without premixing

Info

Publication number: EP2129966A2
Application number: EP08775565.8A
Authority: EP
Inventors: Jérôme Colin; André NICOLLE; Willi Nastoll
Original assignee: IFP Energies Nouvelles IFPEN
Current assignee: IFP Energies Nouvelles IFPEN
Priority date: 2007-02-26
Filing date: 2008-02-14
Publication date: 2009-12-09
Anticipated expiration: 2028-02-14
Also published as: KR101435699B1; RU2009135815A; JP2010519501A; JP5331713B2; US9739482B2; EP2129966B1; FR2913097A1; FR2913097B1; CA2675989C; WO2008122707A3; RU2451877C2; KR20090118036A; US20110027739A1; CA2675989A1; WO2008122707A2

Abstract

The invention relates to a novel porous hydrogen burner for fitting in different types of furnace which require a precise control of the heat flux and, in particular, in vapour reforming furnaces for natural gas or naphtha.

Description

POROUS BURNER WITH HYDROGEN WITHOUT PREMIX

Field of the invention

The invention relates to a new porous hydrogen burner intended to equip different types of furnaces requiring precise control of the heat flow, in particular steam reforming furnaces of natural gas or naphtha intended in particular for the production of hydrogen.

The term hydrogen burner must be understood in a broad sense and means that the fuel of the present burner may be pure hydrogen, but more generally any gas containing hydrogen. The oxidant may be any gas containing oxygen, in particular air, but also enriched or depleted oxygen air. The oxidant can even in a particular case be pure oxygen.

This new burner is in the category of porous burners without premix, because it has a porous element separating the fuel side of the oxidant side, the combustion taking place either inside the porous, or in the vicinity of its outer surface.

More specifically, the burner object of the present invention is a porous burner in the sense that the fuel and the oxidant are introduced on either side of a porous element (also called "porous" later), the internal surface of the porous element being in contact with the fuel, and the outer surface of the porous element being in contact with the oxidant.

The fuel and the oxidant diffuse each on their side of the porous and meet:

-is inside said porous according to a certain heating surface on which will develop an internal combustion. This is called radiant operation or radiant burner.

or near the outer surface of the porous oxidizer side.

The advantages of a porous burner compared to a burner producing a flame, whether this flame is a diffusion or premix flame, are: a reduction of polluting emissions

a combustion with a geometry more controlled than that of a combustion with flame which can pose in addition problems of stability, - significantly improved equipment durability because diluted combustion limits the risk of hot spots,

- the possibility of incorporating in the porous member a combustion catalyst for lowering the combustion temperature to a value close to 500 ⁰ C.

The burner according to the invention is therefore a porous burner, without premix, further having a fuel dispenser member which makes it possible to control the heat flow according to the main dimension of said burner, which will conventionally be called the length of the burner. The thermal flow is controlled by a set of orifices pierced on the surface of the distributor and grouped into sections. Each section groups the orifices of the same diameter.

The distribution of these orifices throughout the dispenser forms an integral part of the invention. In general, the burner according to the present invention will have a fuel distributor having at least two sections, each section being characterized by a given orifice diameter and occupying a certain fraction of the length L of the burner.

It should be noted that the fuel and the oxidant arriving from the two opposite sides of the porous element, the latter does not play the role of a pre-mixing member, but instead of a separation zone of the fuel and the oxidizer.

Moreover, the hydrodynamic conditions, and in particular the fuel velocity in the annular space separating the distributor from the porous element, plays an important role since the stability of the flame is ensured in a restricted range of flow rates. If the flow rate is too low, the flame may extinguish, while if the flow is excessive, the flame may be blown.

Examination of the Prior Art The prior art in the field of porous burners is very broad and it will be limited to patents that report a hydrogen fuel, or predominantly hydrogen, respecting a generally cylindrical geometry. US Pat. No. 5,810,577 describes a porous catalytic burner having two combustion chambers, the first combustion chamber being fed with the fuel and the second chamber being fed with the combustion effluent from the first chamber, the two chambers being separated by a barrier. porous catalyst, with a porosity greater than 50%, and having a pore size of between 1 nm and 1 mm, the thickness of said barrier being between 0.05 and 10 mm.

US Pat. No. 6,699,032 discloses a device for storing a combustible gas which comprises a system for combustion of gases escaping through a safety valve, said combustion system consisting of a burner comprising a porous body surrounding a fuel dispenser. The distribution of the fuel is uniform and the porous body acts as a zone of diffusion or mixing between the fuel and the oxidant.

Brief description of the figures

Figure 1 shows a view of the burner according to the invention in its single tube version.

FIG. 2 represents a view of the burner according to the invention in a more elaborate version in which the oxidant is introduced into a first space adjacent to the porous element, and the smoke from the combustion is recovered in a second space surrounding the first space.

Figure 3 shows a more detailed view of the fuel distributor and an example of a resulting heat flow profile. Figure 4 gives a schematic representation of a burner arrangement according to the invention in a set of tubes to be heated.

Figure 5 is a curve giving the variation of the radial velocity of the fuel on the outer surface of the porous element along the longitudinal axis of the burner. The dashed curve corresponds to a uniform orifice distribution, and the solid line corresponds to a distribution of orifices according to the invention. It is detailed in the context of the example below. FIG. 6 represents the evolution of the hydrogen consumption Y (H2), according to the direction joining the center of the burner to that of the tube to be heated, said direction center to center and is also detailed in the context of the example ci -after.

Brief description of the invention

The hydrogen burner according to the present invention is a burner without premix, of cylindrical geometry of length L and of diameter D, with an L / D ratio of between 10 and 500, and preferably between 30 and 300. The burner according to the invention The invention has a central hydrogen distributor with a non-uniform orifice distribution, and has a porous annular element surrounding the central distributor at least over its entire length L, the thickness of said porous element being between 0.1 and 2 cm, the inner surface of said porous being located at a distance from the central distributor of between 0.5 cm and 10 cm.

The distributor of the burner according to the present invention is preferably divided into a number of sections, the length of each section ranging from 10 mm to 2 m, and preferably from 20 mm to 1.5 m.

The hydrogen burner, according to the present invention preferably has a central fuel distributor, said central distributor is preferably divided into at least two sections, each section having orifices of the same diameter, and at least one section having orifices of a different diameter than the other sections.

More preferably, the central distributor is divided into at least two sections, each section having orifices of increasing diameter with the axial distance along the distributor, in the direction of flow of the fuel.

Even more preferably, the central distributor is divided into at least two sections, each section having orifices of increasing diameter according to a law of the exponential type, in the direction of the fuel flow.

The center to center distance of the orifices of the same section is generally between 0.5 cm and 50 cm, and preferably between 1 cm and 20 cm. The length L of the burner is generally between 2 and 15 m, and preferably between 5 and 12 meters.

The porous element forming an integral part of the burner according to the invention preferably has a porosity of at least 50%, and more preferably of at least 80%.

The porous element may in certain cases have at least two zones of different porosity.

The fuel, usually hydrogen, is preferably introduced into the central distributor at a pressure of between 0.1 and 10 MPa.

According to a variant of the burner according to the invention, the oxidant is preferably introduced into a first annular space surrounding the porous element of the burner, and the combustion gases are collected in a second annular space surrounding the first annular space.

The oxidant preferably circulates in a direction substantially parallel to the longitudinal axis of the burner at a speed of between 1 m / s and 100 m / s, and preferably from 3 to 80 m / s.

The average radial velocity of the fuel relative to the inner surface of the porous material is generally between 2 mm / s and 100 cm / s, and preferably between 0.5 cm / s and 10 cm / s.

The burner according to the present invention can be applied to any type of furnace requiring a well controlled heating of the tubes over their entire length, in particular steam reforming furnaces of natural gas or naphtha.

Detailed description of the invention

The detailed description of the burner according to the invention is carried out by means of FIG. 1 in the basic version and FIG. 2 in the elaborate version.

Figure 3 gives a more precise view of the fuel distributor and is valid both in the basic configuration and in the advanced configuration. The numbers used are the same when they designate the same elements, whatever the figure.

The burner in its basic version comprises: a) a central fuel distributor (1) having a number of orifices (8) grouped together, a family corresponding to a given orifice diameter.

The dispenser will generally be cylindrical in shape with an L / D ratio of between 10 and 500.

In the context of the present invention, this dispenser is fed with the fuel which is available at a pressure preferably of between 0.1 and 10 MPa.

The fuel may be any combustible gas containing hydrogen in any proportion, and possibly be pure hydrogen. b) a porous element (2) of annular shape surrounding the central distributor at least over the entire length of said distributor, and having a thickness between

0.1 and 2 cm, the distance separating the dispenser from the inner surface of the porous element being between 0.5 and 10 cm. The inner surface is defined as being the closest to the dispenser. The porous element surrounds the dispenser in the sense that it has at least the same length as the dispenser, and in some cases, a longer length that allows to clear a space between the end of the dispenser and the inner wall of said porous allowing to improve the degree of combustion of the combustion gas. The porosity of the porous element is at least 50% and preferably greater than 80%. Said porosity is defined as the ratio of the void volume to the geometric volume of any part of the porous element.

This porosity is generally homogeneous over the entire length of the porous element, but it is possible to differentiate it on certain elements of length. For example one can have a first fraction of the length of the porous with a porosity P1 and a second fraction of the length of the porous with a porosity P2 different from P1.

This porous element will typically consist of a metal foam made of an alloy of different metals including for example iron, chromium, aluminum, titanium or zirconium, and in some cases yttrium. An example of such an alloy is the FeCrAIY material sold by the company PORVAIR. The porous element may also consist of a ceramic foam, for example mullite or cordierite. The pore size is generally between 0.2 and 0.6 mm.

The space separating the distributor (1) from the porous element (2), called the annular space (3), plays an important role in the operation of the burner according to the invention since the fuel from the distributor has a certain longitudinal profile of flux it must best retain at the entrance to the porous element. To do this, the linear velocity of the fuel within the annular space should preferably have a sufficiently high value, since it is known that too low speeds would promote the longitudinal diffusion of the fuel within the space. annular (3). Furthermore, obtaining the combustion inside the porous element or in the vicinity of its external surface, is generally more easily achieved when the fuel velocity inside the porous element preferably remains greater than the diffusion rate of the oxidant.

Preferably, however, the fuel velocity must not exceed a limit value to allow the oxidant to diffuse inside the porous element.

Taking into account and optimizing these two conditions lead to adopt a fuel velocity at the entry of the porous element of between 2 mm / s and

1, 0 m / s, and preferably between 0.5 cm / s and 10 cm / s. This speed is precisely defined as the speed taken along an axis perpendicular to the longitudinal axis of the burner, which will conventionally be called radial velocity. This speed is therefore normal to the porous surface.

In the advanced version of the burner according to the invention, the volume outside the porous element (2) is divided by means of a wall (6) substantially parallel to the outer surface of the porous element (2) and of shape substantially cylindrical, in a first space (4) between the outer surface of the porous element (2) and said wall (6), and a second space (5) corresponding to the volume located outside the wall

(6).

This volume outside the wall (6) can be limited by a second wall (7) substantially parallel to the wall (6) and delimiting between said wall (6) and said wall (7) the second space (5). Preferably, this second space (5) will be a space communicating with the first space (4) by its lower part, the substantially vertical wall (7) being then connected to a substantially horizontal wall (8), the walls (7). and (8) then constituting a chamber enclosing the burner according to the invention. In the elaborate version of the burner according to the present invention, the oxidant is admitted into the space (4), joins the fuel inside the porous element (2) or in the vicinity of the outer surface of said porous element (2). ) producing a combustion which generates combustion gases which are found in the first space (4) and are evacuated by passing through the second space (5). Preferably, the linear velocity of the oxidant introduced into the space (4) is between 1 and 100 m / s and preferably between 3 m / s and 80 m / s, and the linear velocity of circulation of the combustion gases in the space (5) is preferably between 2 and 150 m / s.

Example illustrating the invention

The following example is intended to demonstrate the effects of the burner according to the invention from the point of view of fuel consumption and temperature in a direction joining the centers of the burner and the tube to be heated.

In an application of the burner to heating the tubes of a methane steam reforming reactor, the geometric configuration is shown in FIG.

4.

Tubes (T) containing the fluid to be heated and burners according to the invention (B) are staggered with a square pitch.

The distance separating the center of the burner from the center of the tube to be heated is 210 mm.

The length of the burners is 12 meters, the distributor of each of the burners having a length of 10 meters. the L / D ratio of each burner is 120.

The distance between the distributor and the inner wall of the porous element is 15 mm.

The thickness of the porous element is 1 cm.

The distributor is divided into 10 sections of length 1 m. Each section generates a total surface of the orifices arranged on the section considered.

A section is defined as a dispenser portion having orifices of the same diameter.

The total area of the distribution orifices is specified in Table 2 in 2 cases:

- Case 1 corresponds to holes of uniform size on the entire distributor. The surface of all the orifices corresponding to a 1 m section is 15.7 cm ² . This case does not correspond to the invention. It is given for comparison.

Case 2 (according to the invention) corresponds to orifices of increasing size according to the longitudinal distance of the burner, the growth of the total surface of the orifices from one section to the next being of the exponential type. This case corresponds to the invention.

The reagent flow rates and the temperature and pressure conditions are shown in Table 1.

FIG. 5 shows that in the first case, the radial velocity (Ur) of the fuel at the outer surface of the porous element has a large variation along the longitudinal axis (d) of the burner. The curve corresponding to the first case is in dotted line in FIG.

In the second case, because of the distribution law of the orifices, the radial velocity (Ur) of the fuel is much more homogeneous along the longitudinal axis (d) of the burner. This better homogeneity of the radial velocity (Ur) ensures a substantially constant heat flow throughout the tube. The curve corresponding to this second case is in full line in Figure 5. This point is particularly important with tubes whose length is 12 meters. FIG. 6 represents the evolution of the hydrogen consumption Y (H2), according to the direction joining the center of the burner to that of the tube to be heated, said direction center to center. The origin of the distances (r) in this direction is conventionally chosen on the external surface of the porous element of the burner considered. The Y (H2) values are read on the y-axis on the left of Figure 6.

Figure 6 shows that the amount of hydrogen Y (H2) decreases rapidly in the center-to-center direction. Almost 90% of the hydrogen introduced is consumed over a distance of 10 mm, which means that the combustion zone is close to the porous zone. We are in the case of a well localized combustion.

FIG. 6 also shows (on the right of FIG. 6) the evolution of the temperature T of the combustion gases in the center-to-center direction (O ⁰ C = 273 K).

This temperature has a maximum of 1800 K in the vicinity of the outer surface of the porous element, or in the case of the example, 10 mm from said outer surface. The temperature T then decreases to a value of less than or equal to 1200 K. This value is compatible with non-refractory materials, which is particularly interesting in the choice of tube metallurgy and in the economics of the process.

Table 1

Table 2

Claims

1-burner hydrogen, without premix, of cylindrical geometry of length L and diameter D, with an L / D ratio between 10 and 500, and preferably between 30 and 300, having a central distributor of hydrogen with a distribution of non-uniform orifices, and having a porous element of annular shape surrounding the central distributor at least over its entire length L, the thickness of said porous element being between 0.1 and 2 cm, the inner surface of said porous being a distance from the central distributor between 0.5 cm and 10 cm.

2-burner hydrogen, without premix, according to claim 1 wherein the central distributor is divided into at least two sections, each section having orifices of the same diameter, and at least one section having orifices of a different diameter than other sections.

3- hydrogen burner, without premix, according to any one of claims 1 to 2, wherein the central distributor is divided into at least two sections, each section having orifices of increasing diameter with the axial distance along the distributor in the direction of flow of the fuel.

4- hydrogen burner, without premix, according to any one of claims 1 to 3, wherein the central distributor divided into at least two sections, each section having orifices of increasing diameter according to a law of exponential type in the direction of fuel flow.

5-burner hydrogen, without premix, according to any one of claims 1 to 4, wherein the length L is between 2 and 15 m, and preferably between 5 and 12 meters.

6. Hydrogen burner, without premix, according to any one of claims 1 to 5, wherein the center distance of the orifices of the same portion is between 0.5 cm and 50 cm, and preferably between 1 cm. and 20 cm. 7. A non-premix hydrogen burner according to any one of claims 1 to 6, wherein the porous element has a porosity of at least 50%, and preferably at least 80%.

8. The non-premix hydrogen burner according to any one of claims 1 to 7, wherein the porous element has at least two zones of different porosity.

9- hydrogen burner, without premix, according to any one of claims 1 to 8, wherein the hydrogen is introduced into the central distributor at a pressure between 0.1 and 10 MPa.

10- hydrogen burner, without premix, according to any one of claims 1 to 9, wherein the oxidant is introduced into a first annular space surrounding the porous element of the burner, and the combustion gases are collected in a second space annular surrounding the first annular space.

11- Hydrogen burner, without premix, according to any one of claims 1 to 10, wherein the oxidant flows in a direction substantially parallel to the longitudinal axis of the burner at a speed between 1 m / s and 100 m / s, and preferably from 3 to 80 m / s.

12- Hydrogen burner, without premix, according to any one of claims 1 to 11, wherein the average radial velocity of the fuel relative to the inner surface of the porous is between 2 mm / s and 100 cm / s, and preferably between 0.5 cm / s and 10 cm / s.

13- Hydrogen burner, without premix, according to any one of claims 1 to 12, wherein the distributor is divided into a number of sections, the length of each section ranging from 10 mm to 2 m and preferably 20 mm at 1, 5 m. Application of the premixless hydrogen burner according to any one of claims 1 to 13 to a steam reforming oven of natural gas or naphtha.