SE433878B - WAY TO CAUSE IGNITION AND MAINTAIN COMBUSTION OF POWDERED COAL - Google Patents

Description

1so1sv1¿o ning. The amount of such first-class aid required fuels are considerable. Consequently, there is a need for a possible to reduce the amount of auxiliary fuels required for verified coal-fired boilers.

The present invention seeks to eliminate the known disadvantages of the prior art by offering direct ignition of a stream of pulverized coal and air, which is fed to a fuel nare. This object is achieved with the method according to the claim.

The invention is explained in more detail below with reference to to the accompanying drawings.

Fig. 1 shows a section through an arcuate burner for powdered coal which can be used in the practice of the invention, Fig. 2 shows a section through a device for feeding powdered coal, which can be used with the burner according to Fig. 1, and Fig. 3 is a front view of the feeding device according to Fig. 2. i The apparatus shown in the figures is a representative method for performing the direct ignition of a stream of powder carbon and air according to the invention without any significant use of petroleum or natural gas. A solid phase coal / air mixture is used, where the weight ratio between the transport air flow and coal, measured in a discharge line upstream of an incinerator zone, amounts to 1.0 or less. The ignition energy source is so placed, that it is either in or insertable fi the air / coal stream in the combustion zone. The energy that is given off to the air / carbon mixture of the ignition energy source, ignites the carbon the particles. Then the ignition energy source includes an electric high energy arc and the ignition device thus operates on pulsed way, a series of flame pockets are generated.

Furthermore, a secondary air flow to the combustion zone can be corrected by burner secondary air register. Burner secondary air the registers are in a known manner so constructed that an area of circulating air and combustion products (hot gases) are established, wherein the pockets of burning coal are recycled back to it original carbon injection site and the energy in the circulation the area increases until the flame becomes self-sustaining.

In Technology has been successfully applied using 7801871-0 high-energy electric arc as an ignition energy source. Ignition however, the energy source can also consist of a resistance heat device or several such devices or a hydrocarbon fire pilot flame with minimal energy consumption. Conveniently removed the igniter from the flame area, then the presence of the flame has been verified. When a high energy arc supplies ignition energy, the secondary air flow is delayed until its presence of the flame has been confirmed.

In the burner shown in Fig. 1, a ball line is used 16 for pneumatic transport of coal to the ignition zone in the combustion clean. Thus, in the apparatus shown in Fig. 1, the ball conduit 16 left end in connection with the carbon shown in Figs. the feeding device, while the right end of the ball conduit 16 is terminated at a hollow cone, which includes a diffuser mounted on the ball line 16 by means of support 21. An ignition device is immediately downstream of the discharge end of the ball conduit 16. At In the embodiment shown, the ignition device 23 enters through the combustion chamber. side and comprises a high energy arc igniter similar to the type of device currently used for ignition of oil. It should be noted that each ignition source, which provides sufficient energy to sufficiently heat the the actants for ignition can be used. Consequently, a resistance heating device or a small pilot flame, which is used instead of the high energy arc igniter. This is preferred however, due to its reliability and controllability.

The ignition device 23 shown in Fig. 1 is typically mounted. removable so that it can be removed from the incinerator zone and introduced into a protective area after the coal has been ignited.

The burner also includes a secondary air supply line 20, which is coaxial with the ball line 16. The line 20 communicates with an air chamber 14, which is typically cylindrical and has something larger diameter than the conduit 20. The air chamber 14 contains a number of leaves 12. These are arranged to bring the air which comes -in the conduit 20 from the chamber 14, to swirl. An air inlet duct 10 leads to the air chamber 14 from a supply (not shown) of compressed air. The overhead line ends in a material that is difficult to digest. row construction 24, which forms a divergent nozzle. At an out- device for practicing the invention, the ball conduit 16 had a 7801871-o inner diameter of 2.5 cm, the wire 20 had an inner diameter of 15 cm and the structure 24 had a diameter of 33 cm at it open end and a divergence angle of 350.

Figs. 2 and 3 show a device for feeding powdered carbon for supplying a carbon-air mixture to the coal line or the fuel line 16. The feeding device.consists of a pocket 40 for powdered carbon, which can be added to carbon on any known way. Suitably the pocket 40 is dimensioned for storing accessories. sufficient powdered coal to feed the burner during a heating period of the oven at which the burner is to be gagnas. Pocket 40 communicates with the gravimetric worker the feeding device 43. Henna consists of a device 42 with varying bel feed rate, a weight sensitive conveyor 44 and suitable, control circuits not shown. The rotational speed of the feeder 42 is determined by the amount of carbon allowed to fall on the sensitive conveyor 44, and the weight sensed by it, regulates the rotational speed. The gravimetric working food device 43 introduces carbon at a constant speed into a rotating device the air-locked feeding device 46.

The feeding device 46 consists of a cylindrical chamber with blade 47, which has an almost airtight fit with the chamber.

At the bottom of the chamber there is an inlet 48 and an outlet 49. The fit of the blades 47 is such that virtually no one free airway exists between the openings 48 or 49 and the supply device 43. Consequently, it is possible for an air flow, which enters the opening 48, continues out through the opening 49 without to be deflected to the gravimetric feeder 43. The blades 47 rotation for pulverized coal, which is caused to fall on the blades 47 of the feeder 43, into the airway between the openings 48 and 49; Compressed air is supplied to the feeding device 46 by means of a "suitable source 50 at a controlled rate, whereby a carbon-air mixture of a predetermined weight ratio between the air and the coal is supplied to the burner through line 16. According to the present invention has the carbon-air mixture, measured in line 16, a weight ratio of air to carbon of 1,0 or less, preferably 0.5 or less.

In one embodiment, where Class C bituminous carbon, which is increased to 70% minus 200 mesh was used, the upper 7801871-0 the limit of the air-carbon weight ratio to 1.0. The optimal air The carbon weight ratio varies with the type of carbon.

When the burner according to Fig. 1 is to be used, the ignition the inserted device 23 to the inserted position and switched on. An arc ignition device, which generates sparks of an energy of approximately 25 joules and of a duration of about 10 microseconds each and with a repetition rate of 10 Hertz, has been used successfully.

The compressor 50 is switched on as soon as the ignition device starts working, wherein also the gravimetrically operating feeding device 43 started. The compressed air flowing through the rotating, air-locked feeding device 46, results in measured quantities powdered coal and pass this through line 16 and the one with hollow cone provided diffuser 22. Although the burner of Fig. 1 can operate without the diffuser 22, this is considered desirable for insertion of a small amount of circulating gas during the ignition step. The coal air mixing, which is carried in the vicinity of the ignition device 23, was ignited by the energy supplied by the igniter, and the resulting flame propagates through the carbon. As a result ignition occurs, and a relatively unstable flame is present during combustion narens outlet. At this point, an observer 26 or an automatic flame detection device that ignition has occurred and produces a secondary air flow (ambient air or heated air) through the air inlet duct 10. The wings 12 bring the air flow to rotate, giving a helical or swirling air flow, which runs along the conduit 20 and through the structure 24. The latter consists of a divergent nozzle, which enhances the circulatory effect, which naturally occurs as a result of the vortex flow of the air.

The swirling air stream encloses the combustion zone, and as a result of which hot combustion products are withdrawn into the area of injection of new coal. The observable effect of this circulation is that the flame becomes stable, and the stability of the flame is that the ignition device 23 can be switched off and retracted.

The ignition device 23 thus retracted remains in one protected area and is thereby protected from being damaged due to the intense combustion heat. IN It is believed that the direct ignition of powdered carbon, which the present invention offers is successful due to that it offers suitable conditions for the reproduction of the flame in pvso1ev1-o the flowing carbon flow, after the igniter has caused ignition of some of the carbon particles. Over a weight ratio between air and coal of about 1.0, the flame propagates with difficulty hot with unheated air, and direct ignition of powdered consequently, carbon by means of an arc igniter does not work effectively. When the oven is started, there is no preheated air supplied available and can be achieved only at the price of a considerable amount of energy and / or liquid or gaseous fuel. With suitable conditions for the reproduction of the flame, a circulating zone, which contributes to the stability of the collagen obtained.

The circulation means that hot products are withdrawn into the the burning zone, which causes the flame to give rise to its own ignition energy. Whatever the reasons for the success, finding, however, satisfactory direct ignition of the current powdered coal. * The receiver according to Fig. 1 can be used as a heating burners for service boilers. When operating such, the boiler must be provided an elevated temperature for its conventional coal burner to work properly. According to the present invention, the burners can used to give the oven a sufficiently high temperature-for stable combustion with conventional burners. The invention can also applied to obtain both ignition and stabilization at low load.

The described embodiment can be modified in many ways and varied within the scope of the invention.

Claims (1)

7801871 ~ 0 7 PATENT REQUIREMENTS Methods of causing ignition and maintaining combustion of pulverized coal in a combustion zone in the absence of any other fuel and in the absence of sufficient intrinsic ignition energy to ensure ignition, wherein in the combustion zone, consisting essentially of a mixture of pulverized coal and transport air, energy is supplied to (23) the mixture in the combustion zone for igniting the coal in the mixture, the presence of a flame due to the ignition of the carbon in the combustion zone is varied, and that of the ignition of the coal in the combustion zone caused the flame to stabilize, characterized in that a mixture is used which, before it is added to the combustion zone, has a weight ratio between transport air and coal of less than 0.5, that the coal stream is introduced into the combustion zone in the form of a divergent stream, whereby a recirculation flow is established and relatively fine carbon particles is essentially in an upstream direction in relation to the axis of the coal stream migrating into the interior of the digestive fuel stream, so that in it an ignitable mixture is established, that the speed of the coal stream when introduced into the combustion zone is regulated to amount to from 18 - 23 m / sec as a function of carbon particle size and the content of volatiles, that an intermittent electrical discharge is established in the interior of the divergent carbon stream, so that for the ignition of the carbon sufficient energy is introduced into the mixture, and that the flame is stabilized by a rotating flow of unheated secondary air is established in the combustion zone and substantially coaxially around the coal stream after the presence of the flame has been verified.