FR2542065A1 - Method of combustion of a solid fuel and furnace chamber for its implementation - Google Patents

Abstract

The furnace chamber for implementing the method comprises a furnace connected via a transfer pipe to a convection pipe and to an inertia separator. It comprises an electric separator 5 which is equipped with slotted electrodes 11, connected to the inertia separator 5 and equipped with a tube 13 for discharge of the ashy residues and a tube 14 for discharge of the part of the electricity-conducting solid phase communicating with the furnace 1. Application to the combustion of solid fuels in thermal stations, and boiler installations.

Description

PROCESS FOR COMBUSTING A SOLID FUEL
AND FIREPLACE FOR ITS IMPLEMENTATION
The present invention applies to the field of thermics and concerns, in particular, the combustion methods for solid fuels in fireplaces and boilers as well as the firebox for the implementation of this process.

 The invention can be applied mainly to thermal power plants, boiler rooms and industrial flame ovens burning pre-ground solid fuels.

 The fuel residues which appear in the combustion products result from solid unburnt which is mainly due to poor mixing of the fuel with the combustion air, to an insufficient quantity of oxygen in the supply air, at a too low temperature. in the fuel combustion zone, with insufficient fuel grinding rate, poor design of burners, fireplaces, fuel preparation systems. Heat losses due to solid unburnt products commonly reach 2 to 5% and even much higher values when the fuel to be burned has a high ash content. ^ Recycling combustible residues for subsequent combustion would save fuel and / or reduce the costs of preparing the fuel and making the braleurs.

 We know of a solid fuel combustion process in fireplaces and boiler rooms (see for example the work "Thermal power plant", deV.YaRyzhkin, Moscow, 1967) which consists in burning a crushed solid fuel in a hearth room, to evacuate products of combustion containing solid and gaseous phases. Then; the combustion products are passed between electrodes to which a voltage close to 30 kV is applied and the solid phase is deposited on the electrodes.

The solid phase which is deposited is periodically removed from the electrodes and directed into a storage hopper from where the solid phase is injected into the hearth.

 The solid phase thus separated from the combustion products contains a large quantity of purely mineral non-combustible materials, in other words, ash which can reach approximately 90% by weight of the solid phase, which results in unprofitable recycling of the product thus obtained. .

 There is known a hearth chamber intended for the combustion of solid fuel (see the work "Thermal power plant" already cited), comprising a hearth connected by a transfer duct to a convection duct itself connected by a duct to the foyer. he hearth chamber also includes a gas duct through which the combustion products are discharged and a device for the separation of the solid phase from the combustion products.

In addition, the combustion gas circuit comprises a corona discharge electrode and electrodes connected to a suitable high voltage source so as to allow the evacuation of the solid phase of the products of combustion of the fuel from the electrodes using a solid phase accumulation hopper fitted with a tube which connects it to the gas pipe.

 The solid phase separated from the combustion products contains a large amount of non-combustible mineral products. Such an installation does not allow the combustible part to be separated from the mineral part.

 There is also known a method of burning solid fuel in a hearth chamber which consists of mixing ground solid fuel with blown combustion air and heating and bringing the mixture into the hearth to carry out its combustion, to evacuate part combustion products from the convection duct of the hearth chamber and containing the solid and gaseous phases, to mix the products resulting from the combustion with a stream of combustion air blown (see, for example, "Operation of boiler rooms at high pressure in power plants "by PPElizarov, Moscow, Gosenergizdat, 1961, page 31).

 In the process described, only a small part of the fuel residues contained in the reinjected combustion products can be reinjected in post-combustion. The quantity of solid particles present in the flow of fuel combustion products increases, which leads to rapid wear of the elements of the installation housed in the gas pipe.

 There is also known an installation for the combustion of solid fuel comprising a hearth chamber connected by a gas return duct to the convection duct also connected by a duct to the hearth chamber and to an inertia separator also connected to the chamber fireplace (see for example "Boiler rooms" of VPSmirnov, Moscow, Gosenergoizdat, 1959, page 156).

 Such an installation has insufficiencies in the rate of capture of the solid phase in the fuel combustion products and does not make it possible to separate the combustible part from the solid phase and the non-combustible part containing mineral residues.

 It has therefore been proposed to develop a process for burning a solid fuel in fireplaces and hearth chambers for the implementation of the process in which the recycling of the non-burned part of the process, in which the recycling of the unburned part of the products from the combustion is used to carry out an after-combustion which makes it possible to increase the rate of use of the fuel and to ensure a more complete combustion.

 For this purpose; the method of combustion of a solid fuel in a hearth chamber which consists in mixing the ground solid fuel with blown combustion air and heating, bringing the mixture into the hearth of the hearth chamber, to evacuate a part fuel combustion products and containing solid and gaseous phases in a convection duct of the hearth chamber, to mix part of the fuel combustion products with a flow of blown combustion air, is characterized in that the electrically conductive part of the solid phase of the products of combustion of fuel containing combustible residues and the non-conductive part of electricity are separated beforehand, under the action of an electric field, and then mixed the electrically conductive part of the solid phase of the combustion products with a current of blown combustion air and it is reinjected into the hearth for combustion.

 Before separating the electrically conductive part from the solid phase, it is advantageous to ensure a laminar flow regime for the flow of combustion products.

 According to the invention, the hearth chamber for the combustion of a solid fuel comprising a hearth placed in communication by a transfer duct with a convection duct comprising a circuit for reheating the combustion air supplied by a duct returning to the hearth and characterized in that it comprises an electrical separator provided with slit electrodes, disposed at the outlet of an inertia separator and equipped with a pipe for evacuating ash residues and a pipe for evacuating towards the focus of the part of the electrically conductive solid phase.

 it is helpful if the gas bypass duct is flared in the direction of flow of the combustion products.

 it is advantageous that the wall of the transfer duct on which the solid residues of combustion entrained by the combustion gases are deposited, make an angle with respect to the horizontal or greater than the angle of the natural slope of the slope of the solid powdery phase and a deflector is fixed in the vicinity of the lower part of the transfer duct on the wall opposite to that where the solid residues are deposited and at an angle to the horizontal equal to the angle of the slope natural slope of the powdery solid phase.

 it is rational that, in the case where the convection duct is provided with nozzles for heating the blown combustion air and which are mounted vertically inside this duct, the electrical separator is mounted at the outlet of the vertical nozzles, that the tubing for the evacuation of the ash residue is connected to the convection duct and that the tubing for the evacuation of the conductive part of the electricity of the solid phase is placed in communication with the hearth.

 Compared to known processes, the process according to the invention for the complete combustion of solid fuel in boiler rooms and fireplaces has a number of advantages. Thanks to this process, it is possible to separate unburnt carbon particles from the combustion products of the fuel because these particles have an electrical conductivity substantially greater than that of the mineral part of the ash. We can thus separate an aggregate with a high calorific value from the residual products of fuel combustion.

By re-injecting this concentrate into the hearth, the fuel utilization rate is increased. By transferring the flow of combustion products in laminar flow mode, the separation rate between the electrically conductive part of the solid phase and the nonconductive part of electricity is raised by more than 30%.

 The fact that the installation for the combustion of solid fuel is provided with a separator, with slit electrodes9 makes it possible to remove from the flow subjected to separation in the electric field, the gaseous component and to substantially increase the rate concentration of unburnt fuel in the separate conductive part The installation makes it possible to recycle unburnt fuel in the hearth chamber to carry out post-combustion, to evacuate the ashy part of the solid phase in an appropriate receptacle and thus totally eliminate the exhaust of these dusty products into the environment. In addition9 the wear of the heat exchanger tubes housed in the gas convection duct is reduced. By enlarging the transfer duct, the separation rate of the solid phase from the flow of products from the combustion of the fuel is increased. In the case of the use of a convection duct with an ascending current, the installation of a deflector makes it possible to increase the efficiency of the separation of the solid phase and to reduce the influence of the variation of the speed of this flow at the time of the variation of the operating regime of the installation and at the point of inflection of the flow.

In the case of an installation in which a gas convection duct with a downflow of combustion products is provided, the installation of an electrical separator at the outlet of the vertical nozzles makes it possible to separate the part more effectively conductive of the solid phase electricity containing residues of unburned fuel.

Other objects, advantages and characteristics of the invention will appear on reading the description of various embodiments given by way of non-limiting examples, and with reference to the appended drawings in which:
Figure 1 shows in schematic section a combustion installation for solid fuels in which the products of combustion are entrained by an updraft according to the invention;
Figure 2 also shows in schematic section a combustion installation for fuels in which the products of combustion are entrained by a downward flow according to the invention;
Figure 3 shows in section with cutaway a portion of an electrical separator according to the invention mounts at the outlet of vertical nozzles;
Figure 4 shows electrodes of the electrical separator seen in perspective, according to the invention.

 A common method of burning solid fuel in boiler rooms and fireplaces consists of mixing the ground solid fuel with blown and heated combustion air and injecting the mixture formed into the firebox of an installation using the combustion of solid fuel. The products from combustion and containing solid and gaseous phases are evacuated from the convection duct of the boiler room or the hearth chamber. Under the effect of an electric field, the good conductive part of the electricity of the solid phase of the products resulting from the combustion of the fuel is separated from the bad conductive part which contains ash. the solid phase of the fuel combustion products is mixed with a stream of blown combustion air and returned to the hearth.

 To ensure better separation of the good electrically conductive part of the combustion products, a laminar flow regime of the flow of fuel combustion products is used.

 The combustion chamber for implementing the method of combustion of a solid fuel comprises a hearth 1 (FIG. 1), connected via a transfer duct 2 to a convection duct 3.

The convection duct 3 is placed in communication by a duct 4 with the hearth 1. The combustion chamber also includes an inertia separator 5 mounted at the inlet of the convection-ion duct 3.

 In the hearth 1 are installed burners 6 through which is injected a crushed solid fuel arriving from a duct 7 and blown and heated combustion air arriving from the duct 4. At the bottom of the hearth 1 is mounted a hopper a bottom ash 8 in which accumulates the remains of the fuel which are evacuated by a valve 9.

 The combustion chamber comprises an electrical separator 10 provided with slit electrodes 11 connected to a voltage source 12. The electrical separator 10 is provided with a pipe 13 for the evacuation of ashy residues from the fuel and with a pipe 14 for the evacuation of the good conductive part of the electricity from the solid phase of the combustion products via a conduit 15 at the hearth 1.

The tubing 13 for the evacuation of ash residues is connected to an ash receptacle 16. The duct 4 is supplied with air by a fan 17.

 The boiler room which has just been described relates to installations operating with an upward flow of combustion products. In such a heater, the transfer duct 2 widens in the direction of movement of the combustion products, which means that the speed of movement of the flow of combustion products decreases, which contributes to improving the operation of the separator 5.

 The wall 18 of the transfer duct 2 via which the combustion products are discharged, is produced with an angle relative to the horizontal equal to or greater than the angle of the natural slope of the slope of the solid phase. A deflector 20 is fixed to the lower part of the transfer duct 2 on the opposite wall 19 and at an angle a with respect to the horizontal equal to the angle of the natural slope of the slope of the solid phase between 450 and 60 ".

 For boiler rooms using a downdraft of combustion products (see Figure 2), the transfer duct 2 is not flared, but nozzles 21 for heating the combustion air are installed in the convection duct 3 The electric separator 10 is installed at the outlet of the vertical nozzles 21. The evacuation pipe 13 of the ash residue from the electric separator 10 is placed in communication with the convection duct 3 and the evacuation pipe for the part of the phase solid conductor of electricity is connected to the hearth 1 via an intermediate hopper 24 using a conduit 25.

 The nozzles 21 (FIG. 3) serve to heat the air blown for combustion with the aid of the products of combustion which escape and to also provide a laminar displacement regime for the flow of combustion products. The flow of combustion products passes through the nozzles 21 which take the form of parallel conduits traversed by the flow of combustion products and around which the blowing air is discharged. At the outlet of the nozzles 21, the speed of the gases slows down, which allows better separation of the part of the combustion products which conducts electricity.

 The flow of fuel combustion products passes through the slot electrodes 11 (Figure 4) of the electrical separator in which the electrically charged particles are deflected under the action of the electrodes 11 and driven from the air gap 26 through the slots 27 while the uncharged particles fall by gravity under the action of gravitation.

 The hearth chamber forming the subject of the invention and using a solid fuel operates as follows.

 A ground solid fuel is brought through a pipe 7 (FIG. 1) and mixed with heated blowing air introduced through the pipe 4 into the hearth chamber 1. The fuel is then burned in the hearth 1.

The flow of products resulting from the combustion of the fuel is directed towards the transfer duct 2. As the transfer duct 2 is flared, the speed of the flow decreases and the solid particles forming the solid phase of the combustion products are deposited on the wall 18 of the transfer duct 2. The deposited particles slide up to the hopper of the inertia separator 5. The deflector 20 protects the enclosure of the hopper against disturbances caused by the variation in the speed of the flow of combustion products which direct to the convection duct 3.

In addition, the deflector 20 acts as a separator retaining solid particles in the hopper.

 When the direction of flow is reversed in the convection duct 3, the gas speed is minimal, which contributes to causing solid particles to deposit on the deflector 20 from where they slip and arrive in the hopper of the inertia separator 5.

 The gaseous phase, freed from the solid particles of the combustion products, is evacuated in the convection duct 3, while the solid phase pours out from the inertia separator 5 into the electric separator 10 where the particles which conduct electricity and generally consist of carbon are expelled under the action of the electric field of the air gap 26 (Figure 4) through the slots 27 and are directed to the discharge pipe 14 of the electrically conductive part of the solid phase. These particles are entrained by the heated air flow and are sent into the hearth 1 (Figure 1) to maintain combustion. The non-conductive particles of electricity fall between the electrodes 11 and are sent through the tubing. evacuation 13 of ash residues in the ash receptacle 16.

 The combustion of a fuel in the hearth chamber which has a downdraft of the combustion proauits is carried out as follows.

 A crushed solid fuel is brought through a pipe 7 (Figure 2) and mixed with heated blowing air introduced through the pipe 4 into the hearth 1 where the fuel is burned. Then, the flow of combustion products is sent into the transfer duct 2 and then into the convection duct 3. The products of the combustion of the fuel pass through the nozzles 21 where the flow becomes progressively laminar.

Then, the flux is sent to the electrical separator 10 where the solid phase passes through an air gap 26 between the electrodes 11 and is separated into a conductive part and a non-conductive part of the electricity.

The electrically conductive part containing carbon particles is discharged through the slots 27 and is directed by the discharge tube 14 for the electrically conductive part in the intermediate hopper 24. The deposited particles are entrained out from the hopper 22 by a stream of air and are brought into the hearth 1. From the air gap between the electrodes 11, the non-conductive part of the electricity of the solid phase is directed with the flow in gas phase to the convection duct 3. At the outlet of the nozzles 21, the speed of the gas phase decreases suddenly, which facilitates the separation and deposition process of the solid phase.

 Of course, the invention is not limited to the embodiments described above, which can be the subject of numerous variants.

Claims (6)

 1.- Method of combustion of a solid fuel in a hearth chamber which consists in mixing the ground solid fuel with blown and heated combustion air, in bringing the mixture into the hearth of the hearth chamber to make it combustion, to evacuate part of the products resulting from the combustion of the fuel and containing solid and gaseous phases in a convection duct of the hearth chamber, to mix part of the combustion products of the fuel with an air flow of blown combustion, characterized in that the electrically conductive part of the solid phase of the combustion products is separated beforehand using an electric field, mainly containing combustible residues and the non-conductive part of the electricity, then the electrically conductive part of the solid phase of the combustion products is mixed with a current of blown combustion air and is reinjected into the hearth to achieve co mbustion.  2.- Method according to claim 1, characterized in that before separating the electrically conductive part of the solid phase, a laminar flow regime is ensured for the flow of combustion products.  3. A hearth chamber for implementing the combustion method according to claim 1, comprising a hearth connected via a transfer duct to a convection duct comprising a circuit for heating the combustion air. brought by a return pipe to the hearth, characterized in that it comprises an electrical separator (10) provided with slot electrodes (11) and disposed at the outlet of an inertia separator (5) and equipped with a pipe (13) for evacuating ash residues and a pipe for discharging (14) towards the hearth (1) of the part of the solid phase which conducts electricity.  4.- fireplace chamber according to claim 3, characterized in that the transfer duct (2) widens in the direction of flow of the combustion products  5.- hearth chamber according to claim 3 or 4, characterized in that the wall (18) of the transfer duct (2) on which the solid residues of combustion entrained by the combustion gases are deposited makes an angle with respect to horizontally equal to or greater than the angle of the natural slope of the slope of the solid phase, and in that a deflector (20) is fixed in the vicinity of the lower part of the transfer duct (2) on the wall opposite (19) to that where. sue deposit the solid residues and at an angle to the horizontal equal to the angle of the natural slope of the slope of the solid phase,  6.- fireplace chamber according to claim 3, characterized in that in the case where it is provided with nozzles (21 for heating the blown combustion air and which are arranged in the convection duct (3), the electrical separator (10) is mounted at the outlet of the vertical nozzles (21) and the evacuation pipe (14) of the conductive part of the electricity of the solid phase is connected to the hearth chamber (1).