RU2105930C1 - Unit for preparation and burning of water-fuel oil emulsion - Google Patents

Abstract

FIELD: burning of liquid fuels; power engineering. SUBSTANCE: unit includes fuel oil service reservoir 1 connected with coarse filter 3 and gear pumps 6 and 7 by means of pipe line 2. Outlet of pump 7 is connected with outlet of injector 8 through preheater 4 and fine filter 5. Recirculating pipe line 10 is connected to manifold 11 provided with nozzle tips and located in service reservoir 1. Bypass pipe line 16 fitted with gate valve 17 is connected to pipe line 2 on which additional pipe line 18 fitted with gate valve 19 is located. EFFECT: enhanced efficiency. 3 cl, 1 dwg

Description

 The invention relates to the field of techniques for burning liquid fuels in the furnaces of power plants.

Known devices for the preparation of a fuel-water combustible emulsion [1 and 2]
These devices do not provide mixing of fuel and water in large quantities.

Known installation for the preparation of oil-water emulsions, described, for example, [3]
Closest in its technical essence to the claimed invention is a facility for the preparation of an emulsion (a mixture of fuel oil and water), described in [1, p. 43 and fig. 22] This installation comprises a supply tank with fuel oil, to which a coarse filter, a heater, a fine filter, a series of gear pumps, nozzles equipped with recirculation pipelines, the outlets of which are connected to a manifold equipped with nozzle nozzles located in the supply tank, are connected in series. This installation is selected as a prototype.

 The lack of stability of the emulsion is the main disadvantage of the prototype.

 The technical goal of the claimed invention is to eliminate the noted drawback in the developed installation.

 The technical goal is achieved in that the installation for preparation for burning a water-oil emulsion containing a supply tank with fuel oil, a coarse filter, a heater, a fine filter, at least one gear pump, at least one nozzle equipped with a pipeline recirculation of fuel oil, the output of which is connected to a manifold equipped with nozzle tips, located in the supply tank, according to the invention, the pump outlet pipe is connected to starting pipe by the pipeline on which the control valve is located.

 The technical goal is also achieved by the fact that each subsequent gear pump is installed lower performance than the previous one.

 The technical goal is also achieved by the fact that a nozzle located in the mixing chamber of the ejector, the outlet of which is connected through the control valve to the outlet of the first gear pump, is connected to the outlet pipe of the last gear pump, and the displacement chamber is connected by a pipe to an additional consumable capacity.

 The connection of the pump outlet to the inlet pipe by a pipe on which the control valve is located, the installation of each subsequent pump of lower productivity than the previous one, the connection to the outlet of the last pump through the control valve of the nozzle located in the mixing chamber of the ejector, the output of which is connected through the control valve to the inlet the nozzle of the first gear pump, the connection of the mixing chamber of the ejector with a pipeline with an additional flow capacity, these signs are share the novelty of the claimed technical solution.

 Installation for preparing for the combustion of a water-oil emulsion is schematically shown in the drawing.

 The unit will hold the supply tank 1 with fuel oil, which is connected in series with the coarse filter 3 and gear pumps 6 and 7. The output of the pump 7 is connected through a heater 4 and a fine filter 5 with the output of the nozzle 8 through which the fuel oil enters the furnace (to not shown). The direction of movement of the fuel oil is shown by arrow 9.

 To divert part of the fuel oil from the nozzle 8, a recirculation pipe 10 connected to the collector 11 provided with nozzle tips is used. The collector 11 is placed vertically in the supply tank 1. The direction of the fuel oil flow through the recirculation pipeline 10 is shown by arrow 13. The valves 14 and 15 are placed on the pipe 2. The bypass pipe 16 with the valve 17 located on it is connected to the pipeline 2. An additional pipeline is also located on the pipe 2 18, equipped with a valve 19. The direction of movement of fuel oil in the pipe 18 is shown by arrow 20.

 In the pipeline 2 after the output of the pump 7 is connected to the pipe 21, on which the valve 22 is placed.

 The pipe 21 is connected to the entrance to the nozzle 23 located in the mixing chamber of the ejector 24. The direction of movement of the fuel oil through the pipe 26 is shown by arrow 28. The mixing chamber of the ejector 24 is connected by the pipe 29 with an additional flow capacity 30. The direction of movement of the fuel oil through the pipe 29 is shown by arrow 31.

 Installation works as follows.

 When one gear pump 6 is installed in the installation circuit, the flooded fuel oil from the supply tank 1 in the form of a coarse emulsion through the pipe 2 through the coarse filter 3 enters the cavity of the gear pump 6. The valve 17 on the pipeline 16 is closed, and the valve 19 on the pipeline 18 is open . Part of the fuel oil, having passed pump 6, passes through the fuel oil heater 4 and the fine filter 5 to the nozzle 8, and part of the fuel oil returns to the pump inlet 6 again to the pipe 18, mixes with the fuel oil flow coming from the supply tank 1, and again enters the pump 6 . Thus, due to the recirculation of part of the fuel oil through the pump 6, the quality of the preparation of the oil-water emulsion is improved. Since the nozzle 8 has a reverse drain, part of the fuel oil flows through the pipeline 10 back to the consumable container 1. In this case, the fuel oil passes through a vertically located collector 11 and nozzle tips 12 located on it. The jets flowing from the nozzle tips 12 mix the fuel oil in the tank 1, in this case, the water lenses in the container 1 completely disappear and a coarse emulsion is prepared.

 Installation also works as follows.

 In the supply tank 1 there is fuel oil mixed with water, which enters the fuel oil as a result of the discharge of fuel oil from tanks using steam heating. Water can get into fuel oil as a result of leaks in heating systems for fuel oil. The water in the container 1 is in the form of large drops and even in some cases water lenses. The fuel oil is mixed with water (coarse emulsion) through line 2 through the coarse filter 3 to the gear pump 6. In this case, the valves 14 and 15 are fully open and the valve 17 is completely closed. The valve 19 on the pipe 18 is open. Through an open gate valve 15, the fuel oil enters the next gear pump 7, and then into the fuel oil heater 4, where, due to heating, the temperature of the fuel oil rises. Further, the fuel oil enters through the fine filter 5 and into the nozzle 8. Since the capacity of the pump 6 is selected greater than the capacity of the pump 7, the part of the fuel oil flow passing through the pump 6 is returned through the pipe 18 through the open valve 19 to the pump inlet 6, part the same fuel oil enters pump 7. In each of the gear pumps 6 and 7, water droplets disperse with the formation of a water-oil emulsion. Since part of the fuel oil stream is continuously circulating along the circuit: gear pump 6, pipeline 18, open valve 19, pump suction 6, the quality of the preparation of the emulsion is improved. In the pump 7 there is an additional dispersion of water globules and a further increase in the quality of the oil-water emulsion. Thus, the nozzle 8 enters the water-oil emulsion already prepared for burning finely dispersed. Since the nozzle 8 has a reverse drain, a part of the fuel oil flows through the pipeline 10 back to the supply container 1 through nozzle tips 12 located on the vertical manifold 11. In this case, the mixture of water and fuel oil is intensively moved in the container 1, water lenses disappear in the container 1 and a coarse water-oil emulsion is prepared.

 The installation also works as follows in the event that volumes of water contaminated with oil products have accumulated at the production site or in the boiler room, which have been collected and placed in an additional supply tank 30. In this case, the valve 22 is opened on the pipeline 21 and the valve 27 on the pipeline 26. Fuel oil under pressure from the pipeline after the pump 7 enters through a pipe 21 into a nozzle 23 located in the mixing chamber of the ejector 24. In this case, the mixing chamber of the ejector 24 is connected through a pipe 29 to an additional flow tank 30. Outflow yuschaya jet from the nozzle 23 of water-oil emulsion (or pure oil) ejects oil contaminated water from the additional tank 30. The mixture of fuel oil and polluted water passes the throat and diffuser of the ejector and is then fed through line 26 to suction pump 6. The housing 24 of the ejector coarse emulsion is prepared. The amount of contaminated water that is sucked into the ejector 24 is controlled by a valve 22.

 If there is no need to use a water-oil emulsion, the valves 22 and 27 are closed, the valves 14 and 15 are also closed, and the valve 17 is fully open, while the fuel oil is pumped into the nozzle 8 only with the help of pump 7.

 Contaminated water in the additional flow tank 30 is heated if necessary. The heating device is known in the art and is not evaluated in the application materials.

 Compared with the prototype, the quality of the preparation of a water-oil emulsion is improved, which leads to better fuel combustion, which achieves a technical and economic effect.

Claims (3)

 1. Installation for preparing for burning a water-oil emulsion, containing a supply tank with fuel oil, to which a coarse filter, a heater, a fine filter, at least one gear pump, at least one nozzle equipped with a fuel oil recirculation pipe are connected in series, output which is connected to a manifold equipped with nozzle tips, located in the supply tank, characterized in that the outlet pipe of the pump is connected to the inlet pipe by a pipe, and hosting the regulating valve.  2. Installation according to claim 1, characterized in that each subsequent discharge pump is installed at a lower capacity than the previous one.  3. Installation according to paragraphs. 1 and 2, characterized in that the nozzle located in the mixing chamber of the ejector, the outlet of which is connected through the control valve to the outlet of the first pump, is connected to the outlet pipe of the last pump, and the mixing chamber is connected by a pipe with an additional flow capacity.