Introduction

The invention relates to a combustion apparatus, to a fuel burner for a combustion apparatus, and to a method of operating a fuel burner/ combustion apparatus. The invention in particular relates to a burner for operation with air or oxyfuel operational conditions.

Background

In conventional fossil fuel fired combustion equipment as applied to industrial and utility boilers for steam generation the oxygen required to burn the fuel is supplied via atmospheric air. The combustion of the fuel in air releases the chemical energy stored in the fuel as heat, which is then transferred to the water in the boiler to generate steam. Typically the air is supplied to the boiler via burners, which are typically of low NOx design, and via overfire air ports. The boiler may have one or, more typically, a number of burners and overfire air ports. The burners will typically comprise a fuel stream surrounded by one or more air streams; the air streams may be swirled, the swirling air providing the stabilisation of the flame on the burner. The air may be supplied individually to each burner or overfire air port via ducts, or to a group of burners or overfire air ports via a common plenum typically known as a windbox.

In the burner (or burners), the efficiency of combustion (as indicated by the level of carbon monoxide and unburned carbon that remains after combustion is complete) and propensity for the formation of nitrogen oxides (NOx) are related to the quantity of oxygen provided and the rate of mixing of the oxidising media with the combusting fuel. Since the concentration of oxygen in air is fixed, it is necessary to adjust the overall amount of air and/or the proportion of air to the individual registers, and to adjust the proportion of the air supplied to the burners and the overfire air ports to achieve the optimum system performance. However, in a system with fixed burner geometry, the scope for diverting the air from the burners to the overfire air is limited by the minimum flow requirement to the burners that is needed to generate sufficient swirling energy to maintain a stable flame.

In one implementation of the oxyfuel technology for fossil fuel fired combustion equipment, the combustion process will utilise a recycled flue gas stream to which is added upstream of the burners a pure, or nearly pure, oxygen injection stream to produce a single comburant gas which gives combustion process performance equivalent to that of conventional air firing. The oxygen concentration of the comburant gas is variable, and increases with reducing flue gas recycle rate. This approach is sometimes referred to as "simulated air" firing. A proportion of oxyfuel plant is expected to retain an air firing capability.

A feature of "simulated air" firing is that the density of the recycled flue gas and oxygen mixture is generally higher than the air which it replaces and this can lead to reduced local gas velocities within the burner, thereby impairing the stability of a burner designed for air firing when it is operated in oxyfuel combustion mode. Conversely the burner may be designed for adequate gas velocities under oxyfuel firing conditions, leading to excessive pressure drop across the burner when it is fired with air.

Summary of Invention According to a first aspect of the present invention, there is provided a burner for a combustion apparatus comprising:

a fuel input conduit for supplying fuel to the burner;

a combustion gas input conduit for supplying combustion gas to a first stage combustion site;

an overfire gas input conduit for supplying overfire gas to a second stage combustion site;

and

gas supply means;

wherein the gas supply means is adapted to supply gas switchably between:

a first mode of operation wherein air is supplied in suitable proportion to both the combustion gas input conduit and the overfire gas input conduit; and

a second mode of operation wherein an oxygen containing gas other than air is supplied to the combustion gas input conduit and substantially no gas is supplied to the overfire gas input conduit.

The term "oxygen containing gas other than air" is intended to cover a second mode gas supply that includes a proportion of oxygen to support combustion at the first stage combustion site but that is not simply air. In particular it is intended to cover a bespoke gas supply comprising substantially pure oxygen or a mixture of substantially pure oxygen or other oxygen enriched gas (that is, gas with an oxygen content by volume substantially higher than air) and a second gas, wherein the second gas is other than air, and in particular has a reduced nitrogen content relative to air. Preferably the gas supply means is adapted to selectively supply such a mixture to the combustion gas input conduit. The second gas is preferably recycled flue gas. The second mode gas supply thus preferably comprises oxygen enriched recycled flue gas, and optionally further component gases. In other words, the second mode thus comprises an "oxyfuel" firing mode.

The second mode gas supply to the combustion gas input conduit may have any proportion of oxygen capable of supporting combustion at the first combustion site. In a preferred case the second mode gas supply has a proportion of oxygen which generally gives combustion process performance equivalent to that achieved with air for example being around 20 to 50%. That is, the second mode comprises a "simulated air" oxyfuel firing mode.

In accordance with the invention the burner is thus switchable between two modes of operation each having a different gas supply and each having a different combustion process. In the first mode the burner is supplied with air and effects two stage combustion operation, that is, with an appreciable proportion of the total combustion air diverted from the burners to overfire air ports. In the second mode the burner is supplied with a bespoke gas comburant and effects a single stage combustion operation, that is, with notionally all of the oxygen containing comburant supplied via the burners and notionally no combustion gas diverted to the overfire air ports.

The invention in a first aspect thus allows the burner to be operated selectively under air firing conditions or under oxyfuel combustion conditions, in particular "simulated air" oxyfuel combustion conditions, in a manner which optimises the combustion process without the need to change the burner geometry.

The invention in a first aspect thus comprises a burner that is capable of operation with both air and oxyfuel combustion conditions with potential reduction in the negative impacts on flame stability, turndown performance and pressure drop arising from the higher density of flue gas compared to air. Preferably the gas supply means is adapted to switchably supply either air or the oxygen containing gas other than air additionally to the fuel input conduit such that the gas at least assists in transporting the fuel to the combustion chamber. Thus the gas supply means is adapted to switchably supply either air or the oxygen containing gas other than air to both of the fuel input conduit and the combustion gas input conduit.

Preferably the gas supply means includes varying means, such as a baffle or valve means, for varying the proportion of gas supplied to one or both or all where applicable of the fuel input conduit and the combustion gas input conduit and the overfire gas input conduit.

A burner thus comprises a primary fuel input conduit supplying fuel to the burner, a secondary combustion gas input conduit supplying comburant gas to a first stage combustion site, and a selectively operable overfire gas input conduit supplying comburant gas to a second stage combustion site. The combustion gas input conduit may comprise plural fluidly independent input conduits, for example comprising additional tertiary or higher order input conduits, fluidly connected to the gas supply means for supplying air or oxygen containing gas to a combustion site defined by the burner, for example directly to the burner or otherwise to a combustion apparatus in which the burner is located. In a typical arrangement, a primary fuel input conduit may extend along a burner, a secondary combustion gas input conduit may be disposed outwardly of and for example annularly arrayed about the primary fuel input conduit, and higher order combustion gas input conduits, where present, may be disposed outwardly of and for example annularly arrayed about the secondary input conduit in familiar manner. The primary input conduit may be a central conduit extending generally axially along the burner, for example on a burner centreline. Alternatively, the primary input conduit may itself be disposed about a central conduit, for example annularly, with the central conduit serving another purpose. The primary input conduit is still preferably nearer to the centre line than the secondary and higher order conduits, but the primary stream does not necessarily flow along the centreline itself. A conduit may include suitable swirl generation structures to impart an axial swirl to a gas supply therein.

In a more complete aspect of the present invention, there is provided a combustion apparatus comprising:

a combustion chamber; and

at least one and preferably a plurality of burners as hereinbefore described located so as to define combustion sites within the combustion chamber.

Preferably the combustion apparatus comprises a boiler for generating steam.

Preferably the fuel used is coal, most preferably pulverised coal.

Preferably the combustion apparatus includes a flue gas recirculation conduit. Preferably the flue gas recirculation conduit is fluidly connected to the gas supply means and/ or to at least one of the fuel input conduit and the combustion gas input conduit such that a mixture including flue gas may be supplied to the combustion chamber during the second mode of operation. Preferably the flue gas recirculation conduit is fluidly connected to both of the fuel input conduit and the combustion gas input conduit. According to a further aspect of the present invention, there is provided a method of firing a burner in a combustion apparatus selectively in two modes of operation comprising in a first mode of operation:

supplying fuel to the burner;

supplying combustion gas comprising air to a first stage combustion site;

supplying overfire gas comprising air to a second stage combustion site;

causing combustion of fuel to occur in a two stage process;

and in a second mode of operation:

supplying fuel to the burner;

supplying combustion gas comprising an oxygen containing gas other than air to a first stage combustion site;

causing combustion of fuel to occur in a single stage process.

Preferably the oxygen containing gas comprises a mixture of substantially pure oxygen and a second gas having a reduced oxygen concentration relative to air and/ or a reduced nitrogen concentration relative to air. In a preferred embodiment of the second mode, combustion gases are supplied to the combustion site in such manner that the resultant mixture has a proportion of oxygen that produces combustion process

performance equivalent to that achieved with air, for example being around 20 to 50%.

Other preferred aspects of the method, and in particular modes of operation and gas compositions, will be appreciated by analogy.

Summary of Figures The invention is described by way of example only with reference to figures 1 to 3 of the accompanying drawings in which:

Figure 1 is a schematic of a burner suitable for both conventional air firing and oxyfuel firing in accordance with the invention;

Figure 2 is a schematic of the overfire principle;

Figure 3 is a schematic of the oxyfuel process.

Specific Description Figure 1 is a schematic of a simple burner suitable for both air firing and oxyfuel firing in accordance with the invention.

In an air fired mode the combustion air, containing the required oxygen to burn the fuel, is supplied by means of a forced draught fan (FD fan) to individual burners via air ducts, or to groups of burners through a windbox. In the example shown, there are three separate air streams in the burner (1 ); the primary air (PA) which conveys the coal, the secondary air (SA), and the tertiary air (TA); specific burner designs may have fewer or more air streams. In the example shown, the primary air (PA) stream follows the burner axis (11 ) and the secondary air (SA), and the tertiary air (TA) streams are axially directed in ducts concentrically therearound. The burner (1 ) is fired through an outlet in a furnace wall (FW).

In the embodiment the primary air stream is in a central conduit. The invention is not limited to such arrangements. One alternative design option involves moving the primary air (or PFGR/Oxygen/Fuel mix) to a conduit annularly parallel to the central line, but with a central cylinder along the axis used for other purposes (core air and/or for oil/gas igniters). In this case, the primary stream would still be nearer the centre line than the secondary and tertiary streams, but wouldn't flow along the actual centerline.

Dampers (3) control the division of the air between the secondary and tertiary streams (SA, TA). The secondary and tertiary air streams may be swirled, and the extent of swirl may be adjustable. Swirl devices (5) are provided downstream of the dampers for this purpose. Optimisation of the burner with respect to combustion efficiency, emissions, and flame stability is achieved by variation of the total quantity of the air supplied to the burner, the division of the air between the various streams, and the level of swirl applied.

For NOx control a proportion of the total combustion air may be diverted away from the burners as overfire air, and the flow area of the secondary and tertiary annuli may be reduced in proportion so as to maintain the air velocities within the burner registers, and hence maintain the flame stabilisation effect induced by the swirl generation. Figure 2 is a general schematic of the overfire principle, with overfire ports located generally above the burners which may be of the general form illustrated in Figure 1.

The figure shows a typical coal-fired power station arrangement. A combustion chamber (13) is supplied with coal and combustion air via a multiplicity of burners (15). The air supply to each burner is split into primary air (to convey the coal), and secondary and tertiary air to the windbox (16) (the split being to control the mixing and aerodynamics in a low NOx burner). In modern plant a proportion of the combustion air is supplied separately as overfire air through a multiplicity of ports (17) (generally above the burners) to facilitate NOx control. Figure 3 is a schematic of the oxyfuel process. In the "simulated air" exemplification of oxyfuel firing shown here, flue gas is recycled to the coal pulverising mill (21 ) (primary flue gas recycle, or PFGR) and to the windbox (23) containing the burners (not specifically shown in figure 3) (secondary flue gas recycle, or SFGR) by means of dedicated fans (respectively the primary flue gas recycle fan 25 and the secondary flue gas recycle fan 27); there are numerous detailed variants of this process, but they all follow the same generic method. The composition of the recycled flue gas is related to the combustion process, but the stream extracted from the boiler exit will contain low levels of oxygen, typically less than 5% by volume, and insufficient to support combustion. Pure, or nearly pure, oxygen is introduced into the PFGR and SFGR streams to provide the oxidant required to combust the fuel. The composition of the PFGR and SFGR streams will depend upon the detailed implementation of the oxyfuel technology, but typically the PFGR will contain around 20 to 25% by volume of oxygen or higher, whereas the SFGR will contain a significantly higher oxygen

concentration, for example 25 to 50% . The exact concentration levels will be dependent upon a number of factors including the overall furnace stoichiometry, the quantity of flue gas that is recycled to the boiler, the amount of combustion generated moisture that is removed from the recycle stream, the amount of air that leaks into the process, etc. The streams supply burners (not specifically shown) via the windbox (23) to fire the furnace/ boiler (31 ) in generally known manner, with flue gases being drawn off via a particulate removal system (33) to remove solids (ash, etc, 34) and drawn by means of an induced draught (ID) fan (35) to a stack or capture stage (37) as will be familiar. A key process design parameter for the "simulated air" implementation of oxyfuel technology is the quantity of recycled flue gas, usually expressed as a percentage of the total flow in the boiler. This parameter is selected on the basis of maintaining, as far as is possible, the radiative and convective heat transfer properties of an oxyfuel fired boiler relative to air firing; recycle gas flow rates of between 60% and 80% of the boiler gas flow are often quoted. Based upon these typical quantities, and the physical properties of the oxygen / recycled flue gas mixture, it is possible to establish the velocities within the burner when it is operated under "simulated air" oxyfuel firing conditions. As noted previously, gas velocities within the burner are lower for oxyfuel firing than for air firing.

Consider by way of illustration a "Burner A" comprising a simple conventional air-fire operation, and a "Burner B" comprising a stage fired operation switchable in accordance with the present invention. Example operational data are set out in the table below.

Consider "Burner A". This represents a typical unstaged low NOx burner. The primary air velocity is selected to ensure the effective conveying of the transported coal dust to the burner exit, while the tertiary air velocity is selected to ensure sufficient forward momentum through the swirl generators to achieve the required aerodynamics.

In moving to oxyfuel combustion the air is replaced by recycled flue gas (FGR), comprising predominantly CO2 and H ₂ O. The density of the FGR is greater than that of the air which it replaces. Thus there are a number of consequences arising from the operation of "Burner A" under oxyfuel conditions:

1 ) The mass of primary FGR is greater than the mass of primary air so that the primary velocity is maintained at a similar value to the air firing case

2) The mass of tertiary FGR is correspondingly reduced from the value it would otherwise have been

3) Furthermore the density of the tertiary FGR is greater than air

4) The velocity of the tertiary FGR is significantly lower than that of the tertiary air

5) The reduced mass flow and velocity leads to lower tertiary FGR momentum compared to air firing, with an adverse impact on flame aerodynamics

As a result, "Burner A" cannot be operated in both air and oxyfuel firing modes without modification. Now consider "Burner B". This is an air fired burner designed to operate under air staging conditions (where some of the combustion air is diverted away from the burners to overfire air ports). The primary air velocity is maintained to ensure the effective conveying of the coal to the burner outlet as previously, and the burner diameter is reduced so that the tertiary air velocity is maintained at the previous value in spite of the reduced mass flow.

Operating "Burner B" under unstaged oxyfuel firing at the same conditions as defined previously for "Burner A" demonstrates that, by retaining all the FGR flow through the burner, both the primary and tertiary FGR velocities can be maintained at the same value as the staged air combustion operating conditions. Thus "Burner B" can be operated in both air firing and oxyfuel firing modes by provision merely of suitable means to switch supply conditions between the two modes and without any substantive modification to burner geometry.

The invention thus comprises a design of burner that can operate under either air firing or oxyfuel ("simulated air") firing without the need for geometric or other process changes. The burner is sized to operate under air staging conditions with a stoichiometric air to fuel ratio lower than that typical of single stage operation. When operating this burner with the increased mass flowrate for single stage oxyfuel combustion the gas velocities within the burner approach those for conventional staged air firing, and the burner's performance with regard to both flame stability, load reduction, and pressure drop is unimpaired.

The invention allows the burner to be operated under air firing conditions. The invention allows the same burner to be operated under "simulated air" oxyfuel combustion conditions. The invention allows both of the above without the need to change the burner geometry, settings, or relative flow splits between secondary and tertiary (or other) registers.

The invention allows the burner to operate in air or oxyfuel mode with acceptable velocities for the maintenance of both flame stability and acceptable pressure drop across the full normal operational load range of 40% to 110% of the normal rated burner capacity.