RU2542357C1 - Combustion method for liquid organic radioactive waste, and plant for its implementation - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: spraying of waste by an air-stream atomiser and its burning in a cyclone furnace are provided. The cyclone furnace is heated by the heat from the combustion of gaseous or liquid fuel, liquid organic radioactive waste is supplied for combustion continuously, prior to the supply to the air-stream atomiser for spraying, the waste is heated, the air-stream atomiser is cooled by water, the waste is burnt in the presence of fine catalyst particles, secondary air is fed tangentially, cooling and purification of gases are carried out in a bubble column of a jet scrubber first and then in an absorber-condenser. Fuel combustion to heat the cyclone furnace is performed in fluidised bed of catalyst, liquid organic radioactive waste is heated by cooling water of the air-stream atomiser. The plant for liquid organic radioactive waste combustion comprises a cyclone furnace (1) with an air-stream atomiser, a jet scrubber (2), an absorber-condenser (3), water pumps (4/2 and 4/3), a catalytic reactor (7) with fluidised bed of catalyst is used as a starter. The cyclone furnace is mounted on the tank of the jet scrubber, the air-stream atomiser for the supply of liquid organic radioactive waste is located in the upper part of the cyclone furnace.

EFFECT: increased efficiency and environmental safety of liquid organic radioactive waste combustion.

6 cl, 1 dwg, 1 tbl

Description

The invention relates to methods for processing liquid organic radioactive waste, providing the burning of the organic part of the waste to environmentally friendly substances and the conversion of radionuclides and other contaminants into a compact form, convenient for processing by known methods or subsequent disposal.

A known method of processing organic radioactive waste (see RF patent No. 2130209, IPC ⁶ G21F 9/32, 9/14, F23G 7/00, 5/30, 1999). The method includes spraying liquid radioactive waste with a nozzle and burning a granular catalyst in a fluidized bed at a temperature of 600-700 ° C, purification and cooling of hot exhaust gases containing solid particles, sulfur oxides and phosphoric anhydride in series in a cyclone, jet scrubber, absorber-condenser and aerosol filter.

The disadvantages of the method are the complex hardware design, the need to clean the gases from particles formed during the abrasion of the catalyst, poisoning the catalyst with sulfur oxides and phosphoric anhydride, the difficulty of extracting and returning to production of radionuclides, in particular uranium.

The closest in technological essence and the achieved result - the prototype - is a method of processing organic radioactive waste (see RF patent No. 2279726, IPC ⁸ G21F 9/14, 9/20, 2004). The method includes a discrete supply of organic radioactive waste through a pneumatic nozzle to the bottom of a heated reactor, evaporation and burning of waste in the reactor using an ignition source, cooling of hot combustion products when air is supplied to the reactor, then purification of gases from phosphoric anhydride, carbon oxides and nitrogen with sodium hydroxide solution , gas purification from aerosols of sodium hydroxide on an aerosol filter and oxidation of carbon monoxide (II) on a heated copper-containing catalyst, the removal of solid radioactive Waste from the walls bottom of the reactor for subsequent recovery of radionuclides.

The disadvantages of the method are the low efficiency of burning waste due to the low temperature in the combustion chamber, due to periodic purging of the combustion chamber with compressed (cold) air, the formation of hard to remove deposits (pyrocarbon, carbon deposits) at the bottom of the combustion reactor during the processing of mixtures of organic radioactive waste containing high boiling substances, which worsens the conditions of heating and evaporation of the waste, the low efficiency of trapping phosphoric anhydride in a trap with a solution of sodium hydroxide due to instability gas velocity, a variable concentration of carbon monoxide (II) entering the thermal catalytic oxidation reactor.

A device for burning liquid organic radioactive waste is known (see RF patent No. 2386898, IPC ⁸ F23G 7/04, 9/14, 2008). The device comprises a thermally insulated body, a unit for the preparation of waste and air, a combustion chamber and a catalytic nozzle.

The disadvantages of the device are the lack of a system for trapping “acid” gases, as well as the clogging of the catalytic nozzle during the burning of liquid organic radioactive waste containing minerals.

The closest in technological essence and the achieved result - the prototype - is a cyclone reactor for fire neutralization of various types of liquid waste (see Bernadiner MN, Shurygin AP Fire processing and neutralization of industrial waste. M: Chemistry, 1990, p. .70). The reactor contains devices for supplying fuel, liquid waste and secondary air, a combustion chamber and a cyclone chamber.

The disadvantage of this device is the lack of an exhaust gas purification system, without which the processing of liquid organic radioactive waste is impossible.

An object of the invention is to increase the efficiency of burning liquid organic radioactive waste with complete suppression of the release of toxic substances (radioactive dust and "acid" gases) into the atmosphere.

The problem is solved in that in a method for burning liquid organic radioactive waste, including heating a cyclone furnace, spraying waste with a pneumatic nozzle, burning in a cyclone furnace, cooling and purifying gases, according to the invention, heating the cyclone furnace is carried out by heat from the combustion of gaseous or liquid fuel, liquid organic radioactive the waste is fed for incineration continuously, before being fed to the pneumatic nozzle for spraying, the waste is heated, the pneumatic nozzle is cooled with water, the waste is incinerated the cyclone furnace in the presence of fine catalyst particles, the secondary air is fed tangentially, the cooling and purification of gases is carried out first in the foam layer of the jet scrubber, and then in the absorber-condenser, while the combustion of fuel for heating the cyclone furnace is carried out in the fluidized bed of the catalyst, heating liquid organic radioactive waste is carried out with cooling water pneumatic nozzles, the concentration of fine catalyst particles in a cyclone furnace is 100-150 mg / m ³ , the spray liquid the start scrubber is preheated to 60-70 ° C.

The problem is also solved by the fact that in the installation for burning liquid organic radioactive waste containing a starter, a cyclone furnace with a pneumatic nozzle, a jet scrubber, an absorber-condenser, water pumps, according to the invention, a catalytic reactor with a fluidized bed of catalyst is used as a starter, a cyclone furnace is installed on the tank of the jet scrubber, and a pneumatic nozzle for feeding organic radioactive waste is located in the upper part of the cyclone furnace.

Preheating the furnace is necessary to initiate the process of burning liquid organic radioactive waste, since it includes not only atomization, but also evaporation of the waste.

The fluidized bed of the catalyst is not only a source of heat for rapid heating of the cyclone furnace, but also a generator of fine catalyst particles formed during its abrasion and used to realize aerosol catalysis - the oxidation of products of underburning of heavy oils and spent extraction mixtures when burning liquid organic radioactive waste (see RF patent No. 2081695, IPC ⁶ B01J 8/08, B01J 8/32, 1997). Secondary air in a cyclone furnace is supplied to improve waste incineration conditions.

The continuous supply of liquid organic radioactive waste for incineration and the tangential supply of secondary air ensures high temperature and completeness of waste combustion in a cyclone furnace.

The high temperature at the entrance to the foam layer of the jet scrubber provides intensive evaporation of water, the enhanced condensation of which in the absorber-condenser increases the efficiency of trapping radioactive dust and “acid” gases.

Heating the waste before feeding heated air to the pneumatic nozzle and cooling the pneumatic nozzle improves the conditions for atomization and subsequent evaporation of liquid organic radioactive waste. There is no need for cyclone exhaust gases.

Heating the irrigation fluid in the jet scrubber tank to 60-70 ° C ensures stable operation of the gas cleaning system during the start-up of the cyclone furnace.

The use of a catalytic reactor with a fluidized bed of catalyst as a starter ensures smooth heating of the cyclone furnace.

The location of the cyclone furnace on the jet scrubber tank allows to reduce the dimensions of the installation, to eliminate the dispersion of high potential heat, and, together with the location of the pneumatic nozzle for supplying organic radioactive waste in the upper part of the cyclone furnace, allows you to create conditions for providing shock-inertial capture of solid particles of aerosols by the liquid surface in the jet scrubber tank.

The invention is illustrated in the drawing.

The drawing shows a diagram of a plant for the processing of liquid organic radioactive waste with a catalytic reactor containing a fluidized bed of catalyst, as a starter and a system for purifying exhaust gases.

The liquid organic radioactive waste incineration plant comprises a cyclone furnace 1 with water-cooled pneumatic nozzles, a jet scrubber 2 with heaters installed in its tank, an absorber-condenser 3, pumps 4 / 1-4 / 2, a fan 5, a heat exchanger 6, and a catalytic reactor 7.

The method is implemented, and the installation works as follows.

Start the cyclone furnace 1 with its heating by heat from the combustion of organic fuel (natural gas or liquid hydrocarbons) in a fluidized bed reactor of a granular oxide catalyst IK-12-72. The launch time of the cyclone furnace is 1-1.5 hours.

When the heating temperature of the cyclone furnace 1 is reached, the values of 700-800 ° C supply liquid organic radioactive waste for incineration using a water-cooled pneumatic nozzle. Secondary air is supplied tangentially. Maintain the ratio: supplied air to the pneumatic nozzle: secondary air = 1: 3-4.

The catalytic reactor 7 is a generator of finely dispersed solid particles of the catalyst due to its abrasion, therefore, deep oxidation of mixed organic waste occurs in a cyclone furnace 1 with the participation of finely dispersed catalyst particles. The temperature of the gases inside the combustion zone of the cyclone furnace 1 reaches 1000-1100 ° C.

Waste gases with temperatures up to 850-900 ° C are fed into the tank of the jet scrubber 2, where, with a sharp change in the direction of the gases, large particles are captured by the liquid surface.

Next, the gases enter the foam layer of the jet scrubber 2 for cooling and cleaning of small particles and gaseous pollutants. The temperature of the gases in the foam layer of the jet scrubber drops from 850-900 ° C to 70-80 ° C. To maintain the foam layer and create a pressure drop in the cyclone furnace, a fan 5 is used.

The irrigation solution is supplied to the jet scrubber 2 by a water pump 4/1. In order to prevent the transfer of droplet moisture, the jet scrubber 2 is equipped with an effective drop eliminator installed in the upper part.

Then the gases enter the absorber-condenser 3, designed for the purification of gases from small particles and gaseous pollutants. The temperature in the absorber-condenser drops from 70-80 ° C to 25-30 ° C. The water supply to the absorber-condenser is carried out by a water pump 4/2 through the nozzle installed in the upper part of the absorber-condenser 3. The purified gases are discharged by the fan 5 into the existing ventilation.

An example of the method and parameters of burning a mixture of kerosene and VM-1 vacuum oil containing 4.5 mg / l of uranium in a cyclone furnace with a waste productivity of 1.0 kg / h at a temperature of t = 950-1000 ° C using a granular oxide catalyst IR-12-72 (dust concentration of the catalyst is 0.1-0.15 g / m ³ ) are shown in the table. It also provides data on incineration without the use of a catalyst.

Table The composition of the gases when burning a mixture of kerosene and vacuum oil VM-1 No. Substance Dimension Substance concentration Catalyst IR-12-72 No catalyst one O ₂ % vol. 13.5 13.5 2 CO ₂ % vol. 4.2 4.2 3 CO mg / m ³ 37-41 140-150 four SO ₂ mg / m ³ 0 0 5 NO mg / m ³ 1-2 1-2 6 NO ₂ mg / m ³ 0 0 7 U _total mg / m ³ 0 0

Thus, the burning of liquid organic radioactive waste according to the claimed method using the proposed installation can improve the efficiency of combustion while achieving complete suppression of the release of toxic substances (radioactive dust and "acid" gases) into the atmosphere.

Claims (6)

1. A method of burning liquid organic radioactive waste, including heating the cyclone furnace, spraying the waste with a pneumatic nozzle, burning in a cyclone furnace, cooling and purifying gases, characterized in that the heating of the cyclone furnace is carried out by heat from the combustion of gaseous or liquid fuel, liquid organic radioactive waste is fed to incineration continuously, before feeding into the pneumatic nozzle, the waste is heated, the pneumatic nozzle is cooled with water, the waste is burned in a cyclone furnace in the presence of fine particles atalizatora, secondary air is supplied tangentially, cooling and gas purification is carried out initially in the foam layer of the jet scrubber, and then in the condenser-absorber. 2. The method according to claim 1, characterized in that heat from the combustion of gaseous or liquid fuel in the fluidized bed of the catalyst is used to heat the cyclone furnace. 3. The method according to claim 1, characterized in that the heating of liquid organic radioactive waste before feeding into the pneumatic nozzle produce cooling water pneumatic nozzle. 4. The method according to claim 1, characterized in that the concentration of fine catalyst particles in a cyclone furnace is 100-150 mg / m ³ . 5. The method according to claim 1, characterized in that the irrigating liquid of the jet scrubber to start up is preheated to 60-70 ° C. 6. Installation for burning liquid organic radioactive waste, including a starter, a cyclone furnace with a pneumatic nozzle, a jet scrubber, an absorber-condenser, water pumps, characterized in that a catalytic reactor with a fluidized bed of catalyst is used as a starter, a cyclone furnace is installed on the jet scrubber tank and a pneumatic nozzle for supplying organic radioactive waste is located in the upper part of the cyclone furnace.