RU173977U1 - BOILER INSTALLATION - Google Patents

Abstract

The utility model relates to marine technical means for preventing oil pollution and is intended to increase the efficiency of oil-containing water disposal. The boiler installation includes a boiler with a fuel nozzle and a gas duct, as well as a boiler fuel system containing a fuel type switch connected in series, a fuel pump, a coarse filter, a fuel heater, a fine filter, and the output of the fine filter is connected to the input of the fuel nozzle, as well as connected in series oil residue tank and a water-fuel emulsion preparation system, a supply tank, while one input of the fuel type switch is connected to a consumption tank, and the other to the output of the oil-fuel emulsion preparation system, the boiler also contains an oil-containing water nozzle, and the oil-containing water system enters the fuel system of the boiler, including oil-containing water tank connected in series, coarse filter, pump, fine filter and oil-containing water heater, the input of which is connected to the outlet ohm fine filter, and an output connected to the input injector oily boiler waters.

Description

The utility model relates to marine technical means for the prevention of environmental pollution by oil and is intended to increase the efficiency of the utilization of oily waters.

A useful model of the device on ships for the purification of oily water is known, containing a collection tank, sedimentation tanks, coarse, fine filters and a control system (see, for example, Ship Mechanics Thermal Engineering Handbook / I.F. Koshelev, A.P. Pimoshenko, G.A. Popov, V.Ya. Tarasov. - L: Shipbuilding, 1987, - 480 s: p. 412-413). Oily water from the collection tank is given out to sedimentation tanks. In the process of sedimentation, oil products are separated from the water, they rise up, and the water falls into the lower part of the tank, from where it is fed to the coarse and fine filters and then to the control system. To speed up the settling process, heating is usually used. If the concentration of oil products in the treated water is acceptable, it can be dumped overboard, otherwise it will be further processed. Here, the process of purification of oily water is quite slow and requires significant energy costs.

A useful model of a device for cleaning oil-containing water in the form of oil-water separators of the type SK, SKM, USKG, separators of the type OV and others is known (see, for example, the Handbook of a ship mechanic in heat engineering / I.F. Koshelev, A.P. Pimoshenko, G. .A. Popov, V.Ya. Tarasov. - L: Shipbuilding, 1987, - 480 p .: p. 414-419). Such separation plants are expensive, occupy a significant place in the engine room, require qualified maintenance and repair, so their installation is not always advisable.

A useful model of incinerator is known that can be used for the disposal of oily waters (see, for example, Operation of ship auxiliary mechanisms, systems and devices: a training manual / A.M. Te. - Vladivostok: Mor. State University, 2014 - 178 pp.: Pp. 161-168, as well as a Ship mechanic.A manual in 3 volumes edited by A.A. Fock -Rostov n / A: Phoenix. 2010. - 1032 pp. Volume 2, section Ship incinerators.). However, in these devices, as a rule, oil-containing water with a high content of oil residues is disposed of, and a certain fuel consumption, usually diesel, is required to ensure the operation of the incinerator.

The closest in technical essence and the achieved result is a utility model of a boiler plant designed for the disposal of oil-containing water (see patent for utility model No. 138869 "Boiler installation" by application No. 2013136000 of July 30, 2013, authors A. Chichurin, Sadekov M.Kh.). The boiler installation includes a boiler with a fuel nozzle and a gas duct, as well as a boiler fuel system containing a fuel type switch, a fuel pump, a coarse filter, a fuel heater, a fine filter, the fine filter output being connected to the fuel nozzle inlet, and connected in series to a tank of oil residues and a system for preparing a water-fuel emulsion, a supply tank, while one input of the fuel type switch is connected to the supply tank, and d the other is to the exit of the oil-fuel emulsion preparation system, the boiler also contains an oil-containing water nozzle, and the boiler fuel system is an oil-containing water system including a series-connected oil-containing water tank, a coarse filter, a pump, a fine filter, and the output of the fine filter is connected to the nozzle inlet oily boiler water.

This utility model provides for the utilization of oily water by burning it in a boiler furnace. To do this, in the steady-state mode of operation, the contents of the oil-containing water tank in a certain proportion to the fuel are given to the oil-containing water nozzle at the same time as the fuel delivered to the fuel nozzle to the boiler furnace. The flow of oily water discharged to the oily water nozzle is controlled by changing the pump supply of the oily water system, from the condition of ensuring a normal combustion process in the boiler furnace. This flow rate will depend on the content of petroleum products in the water, and when their content is low, it usually does not exceed 10 ... 15% of the fuel consumption (see, for example, Enin V.I., Denisenko N.I., Kostylev II. Ship boiler plants : textbook for universities.M .: Transport, 1993.216 s, p. 3.3). Oily water entering the nozzle of oily water is sprayed in the boiler furnace, heated to the boiling point of water and evaporated. At the same time, oil products from the composition of oil-containing water are burned up, and the water turns into steam and, together with the products of combustion, goes into the gas duct.

As follows from the above, one of the steps that oily water must go through during the disposal process is to heat it in the boiler furnace to the boiling point, which requires a certain amount of heat released in the boiler furnace during fuel combustion. If this process (heating the oil-containing water in the boiler furnace to the boiling point) were absent, then this useful model would allow increasing the amount of utilized oil-containing water by a value proportional to the heat consumption for heating the oil-containing water to a boil.

The objective of the utility model is to increase the efficiency of the utilization of oily water by burning in the boiler furnace by heating them before being fed into the boiler furnace.

The objective of the utility model is achieved by the fact that in a well-known boiler installation, including a boiler with a fuel nozzle and a gas duct, as well as a fuel system of a boiler containing a fuel type switch connected in series, a fuel pump, a coarse filter, a fuel heater, a fine filter, and the output The fine filter is connected to the inlet of the fuel injector, as well as a series-connected tank of oil residues and a system for preparing a fuel-oil emulsion, a consumable tank, one input of the fuel type switch is connected to the supply tank, and the other to the output of the fuel-oil emulsion preparation system, the boiler also contains an oil-containing water nozzle, and the oil-containing water system includes a series of oil-containing water tanks, a coarse filter, a pump, fine filter, an oil-containing water heater is additionally introduced into the oil-containing water system, the input of which is connected to the output of the fine filter, and the output is connected to the input at the oil-containing boiler nozzle.

The essence of the utility model is as follows. In a known utility model (prototype) in a steady-state mode of operation, the contents of the oil-containing water tank in a certain proportion to the fuel are output to the boiler furnace simultaneously with the fuel delivered to the fuel nozzle, to the oil-containing water nozzle. Oil-containing water entering the nozzle of oil-containing water is sprayed in the boiler furnace, heated to the boiling point of water and evaporated. At the same time, oil products in the composition of oil-containing water are burned up, and the water from their composition turns into steam and together with the combustion products goes into the gas duct and further into the pipe. In this case, the amount of oil-containing water utilized is determined by the type of boiler, its operating mode, and the content of oil products in the oil-containing water being utilized.

In the proposed utility model, oil-containing water is heated to a temperature close to the boiling point of water (90 ... 99 ° C) before being supplied with oil-containing water to the nozzle. As a result, the utilized oily water after evaporation in the furnace of the boiler evaporates almost immediately, that is, there is no heat in the boiler furnace to heat the oily water to a boil. Therefore, it becomes possible to increase the amount of oily water supplied to the furnace for disposal, that is, the efficiency of oily water disposal is increased.

Thus, the claimed utility model has a new property, which consists in supplying heated oil-containing water to a boiler furnace in a certain proportion to fuel. As a result, the utilized oily water after evaporation in the boiler furnace evaporates almost immediately (there is no heat in the boiler furnace to heat the oil-containing water to a boil) and burn out. This property does not coincide with the properties shown by the distinguishing features in the known solutions and is not equal to the sum of these properties, and ensures the achievement of a new positive effect, which consists in the possibility of increasing the amount of oil-containing water supplied to the boiler furnace for disposal, that is, the efficiency of oil-containing water disposal is increased.

In FIG. The block diagram of the boiler plant is given.

The boiler installation includes a boiler 1 with a fuel nozzle 2 and a gas duct 3, as well as a fuel system of a boiler 4 containing a fuel type switch 9 connected in series, a fuel pump 8, a coarse filter 7, a fuel heater 6, a fine filter 5, and a fine filter output purification 5 is connected to the input of the fuel nozzle 2, as well as a series-connected tank of oil residues 12 and a system for preparing water-fuel emulsion 11, a supply tank 10, while one input of the switch of the type of fuel 9 is connected to the flow the bottom of the tank 10, and the other to the outlet of the water-fuel emulsion preparation system 11, the boiler 1 also contains an oil-containing water nozzle 13, and the oil system of the boiler 4 includes an oil-containing water system 14 including a series-connected oil-containing water tank 18, a coarse filter 17 pump 16 , a fine filter 15 and an oil-containing water heater 19, the input of which is connected to the output of the fine filter 15, and the output is connected to the input of the oil-containing water nozzle 13 of the boiler 1.

The boiler installation works as follows.

Normal modes of the boiler installation are operation on the main fuel supplied from the supply tank 10 (fuel type switch 9 in position B), or on the fuel-oil emulsion supplied from the fuel-oil emulsion preparation system 11 (fuel type switch 9 in position A). The transfer of the boiler plant to the mode of burning oily water is allowed after the boiler 1 is sufficiently warmed up in the normal operating modes. To do this, the pump 16 is turned on. At the same time, the oil-containing water from the oil-containing water tank 18 by the pump 16 through the coarse filter 17, the fine filter 15 of the oil-containing water system 14 will be discharged to the oil-containing water heater 19 and then to the oil-containing water nozzle 13 of the boiler 1. In the heater oily water 19 is heated oily water to a temperature close to the boiling point of water (90 ... 99 ° C). Heated oily water to a temperature close to the boiling point of the water entering the nozzle of oily water 13 is sprayed in the furnace of boiler 1 and evaporates almost immediately. At the same time, there is no heat cost for heating the oil-containing water to the boiling point of water (in the prototype, the process of heating the oil-containing water sprayed in the boiler furnace 1 to the boiling point of water occurs, that is, there is a cost of heat released in the furnace during fuel combustion). In the furnace of boiler 1, oil products in the composition of oil-containing water are burned, and water from their composition is converted into steam and together with the combustion products goes into the gas duct 3. The flow of oil-containing water discharged to the nozzle of oil-containing water 13 is controlled by changing the capacity of the pump 16 of the oil-containing water system 14, from the condition of ensuring a normal combustion process in the boiler furnace. In the proposed utility model, this flow rate will be slightly higher than in the known utility model, since the missing heat costs in the furnace of boiler 1 for the evaporation of oily water can be used to increase the amount of utilized oily water.

Thus, the claimed utility model has a new property, which consists in supplying oil-containing water to the boiler furnace 1, heated in the oil-containing water heater 19, in a certain proportion to the fuel. As a result, the oily water to be disposed of after being sprayed in the furnace of the boiler 1 evaporates almost immediately (there is no heat in the boiler furnace to heat the oil-containing water to a boil) and burn out. This property, which does not coincide with the properties shown by the distinguishing features in the known solutions and is not equal to the sum of these properties, provides a new positive effect, which consists in the possibility of increasing the amount of oil-containing water supplied to the furnace of boiler 1 for disposal, that is, the efficiency of oil-containing water disposal is increased.

Claims (1)

A boiler plant including a boiler with a fuel nozzle and a gas duct, as well as a fuel system of a boiler containing a fuel type switch, a fuel pump, a coarse filter, a fuel heater, a fine filter, the fine filter output being connected to the fuel nozzle inlet, and also connected in series to a tank of oil residues and a system for preparing a water-fuel emulsion, a supply tank, while one input of the fuel type switch is connected to the supply tank, and the other, to the exit of the oil-fuel emulsion preparation system, the boiler also contains an oil-containing water nozzle, and the oil-containing water system, including a series-connected oil-containing water tank, a coarse filter, a pump, a fine filter, characterized in that it is included in the fuel system of the boiler In addition, an oil-containing water heater was introduced into the oil-containing water system, the input of which is connected to the output of the fine filter, and the output is connected to the input of the oil-containing water nozzle of the boiler.

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