RU2073926C1 - Gas producer for radioactive row waste lumber processing - Google Patents

Abstract

FIELD: radioactive material engineering, thermal treatment technology. SUBSTANCE: gas producer for combustible radioactive material waste processing has base gas generator and reburning gas generator, first is equipped by reprocessing shaft, fire greed, branch pipe for gas removing, air feeder for row waste oxidizing, top and bottom hatching ports for waste loading and hard remainders disposal. Output port is connected with reburning gas generator which has device for ash disposal. For better operational safety while waste lumber processing base gas generator has moisture removing system which has condenser and blower placed consequently along gas flow pass. Moisture removing system input is connected to shaft upper part by throttle device but output is connected to air feeder for row waste lumber oxidizing. Condenser output for condensate and slime disposal is connected to vaporizer which works by base gas generator output pipe heat exchange to vaporizing channel using. Vaporizer output heated channel is connected to blower diffuser but slime output is connected to ash disposal device. EFFECT: higher operational safety, more dip radioactive row waste lumber reprocessing. 1 dwg

Description

 The invention relates to the field of technology for the management of radioactive waste (RW), namely, combustible RW, the compaction of which is carried out due to their thermal processing.

 Currently, the most common method of thermal processing of combustible radioactive waste is burning, see, for example, Sobolev EA Khomchik L.M. "Disinfection of radioactive waste at centralized sites." M. Energoatomizdat, 1983, p. 19.35. At the same time, over 90% of radionuclides remain in the ash residue, which is known in the known methods: cementing, vitrification, etc., and sent for burial.

 However, the known methods of combustion have a significant drawback, namely that flue gases require cleaning of the remaining radionuclides to 10% of those contained in the waste, and the large volume of gases produced by combustion increases the dimensions and costs of the gas cleaning system.

 Gasification can be considered as one of the methods of compacting solid combustible waste, which, compared with burning, can significantly reduce the volume of gas purification. In this case, non-flue gases with a significant excess of air are subject to cleaning, and the generator gas produced with a lack of air, the volumetric output of which is approximately 2 times less than the volume of flue gases from the same amount of source material.

 There are various gas generators for the processing of combustible waste. For example, in an article by A. Salamov. "Installations for the combustion and gasification of wood waste", the journal "Industrial Energy" 2, 1985, p.52 54.

 However, the known gas generators do not provide for the processing of radioactive waste, the percentage of underburning is high, which increases the volume of radioactive substances to be disposed of and increases the costs of conditioning and disposing of the ash residue.

 Gas generators with rotating milling (or other type) gratings are also known, which provide continuous removal of ash and slag and thereby increase indicators of gas quality, productivity and burning residues, for example, gas generators described in D. B. Ginzburg's book "Gasification of solid fuel " M. Gosstroyizdat, 1958, p. 24 30, Fig. 2.4.

 However, in these constructions the under-burn is 5.12% (see ibid., P. 97), which leads both to energy losses and to an increase in the cost of RW disposal.

 Of the known technical solutions, the closest object to the claimed one is the "Gas generator for the processing of combustible radioactive waste" described in the "Explanatory note to the technical proposal for the technology of gasification of organic (wood) radioactive waste and the choice of gas generator design" ANK ITMO A.V. Lykova, Minsk, 1991. 54 - 63, Fig. 21, and accepted by the authors for the prototype.

 The gas generator adopted for the prototype is intended for the processing of wood radioactive waste, contains the main gas generator and the afterburner, while the main gas generator is equipped with a waste processing shaft, grate, nozzles for exhaust gas, for supplying air for oxidation, for supplying waste from above and for removing from below solid residue, while the pipe for discharging solid residue is connected to the afterburner equipped with a device for removing ash.

 The gas generator adopted for the prototype ensures high completeness of combustion during the processing of various wood waste, which, in the case of radioactive waste, ensures a minimum cost for the disposal of ash, into which the bulk of the radionuclides are transferred.

 However, in the processing of logging residues and contaminated forest litter, which have high humidity, a significant disadvantage of the prototype is manifested, which consists in the instability of the gas generator operating modes when the moisture content of the initial fuel fluctuates, worsening the quality of the generator gas, as well as to problems during ignition, which leads to increased danger when processing radioactive contaminated wood, as excess moisture and resinous substances lead to a fast clogging of gas purification filters, to the breakthrough of radioactive aerosols into the fuel path of the engine and into the environment. In addition, with high humidity of the source material, the combustion mode in the main gas generator may be disrupted with the termination of the entire process.

 The objective of the invention is to increase safety in the processing of radioactive waste, which can be achieved by increasing the stability of the operating modes of the gas generator.

 The problem is solved in that in a gas generator for processing wood radioactive waste containing a main gas generator and an afterburner, while the main gas generator is equipped with a waste processing shaft, a grate, nozzles for exhausting the generator gas, for supplying air for oxidation, for supplying waste from above and for removal of solid residue from below, while the pipe for removal of solid residue is connected to the afterburner equipped with an ash removal device according to the invention The gas generator is equipped with a dehumidification system, including a condenser and a fan located in series along the gas stream, while the system input is connected through the throttle device to the upper zone of the mine, the outlet to the pipe for supplying air for oxidation, and the condenser and sludge outlet are connected to the evaporator, connected on the heating side to a pipe for exhausting gas from the main gas generator, the outlet of the evaporator on the heated side by gas is connected to the inlet to the fan, and the output to the sludge from th to remove the ash.

 A distinctive feature of the claimed invention is the presence of the main gas generator of an additional closed loop drying of the source material. This dehumidification system is equipped with a condenser and a fan located in series along the gas flow, while the input of the system is connected through the throttle device to the upper zone of the mine, the outlet to the pipe for supplying air for oxidation, and the condenser and sludge outlet is connected to the evaporator connected via heating side to the pipe for exhausting gas from the main gas generator, the evaporator outlet on the heated side is connected to the fan inlet by gas, and the sludge outlet with a device for removing ash .

 Since overpressure is created in the mine due to blasting, the throttle sets the gas flow rate for drying the fuel. The gas was taken in the upper zone of the mine, due to which the gas taken out, heated in the oxidation zone of the gas generator, passes through the entire fuel layer and carries away the main amount of moisture and some resinous substances to the moisture removal system. However, the sampled gas also captures finely dispersed solid particles and aerosols containing radioactive substances, and therefore it is the closed circuit of the moisture removal system that ensures safety in the processing of radioactive wood waste.

 Features of connecting the equipment of the moisture removal system (connecting the outlet from the system of air purified from moisture and resinous substances to the air supply zone for oxidation of the main gas generator, supplying condensate and slag from the condenser to the evaporator, separating them there by the heat of the generator gas into the evaporated volatile gas fraction and into non-evaporated slags, the connection of the gas outlet from the evaporator to the fan inlet of the dehumidification system, and the output to slag with a device for removing ash) allows optimal allocate the selected moisture for blowing the steps gasifier, and a non-evaporable residue containing radioactive contamination immediately forward for processing, thereby minimizing the possibility of contamination in the product gas.

 With an increase in the water supply to the gas generator to a value of 0.4 kg of steam per 7 kg of fuel, the amount of reacted water vapor increases, as a result of which the amount of hydrogen in the gas increases, and the percentage of carbon monoxide decreases. In this case, the calorific value of gas reaches the most optimal indicators (see P. T. Tokarev. "Gas-generating cars". M. Mashgaz, 1955, p. 35).

 Thus, the above distinguishing features, despite a certain complexity of the design, making it possible to control the moisture distribution in the fuel processing zones, increase the reliability of regulation of the gas-generating process and thereby increase the degree of fuel processing, which reduces the amount of solid radioactive waste received at the facility, and thereby increase the safety of her work.

 The drawing shows a schematic diagram of the inventive gas generator for processing wood radioactive waste.

 The installation comprises a main gas generator 1, equipped with a loading hopper 2, and an afterburner gas generator 3 located below it, equipped with an ash removal device, for example, a removable container 4. The gas generator is equipped with a fuel processing shaft 5, a grate 6, nozzles for the discharge of general gas 7, air supply for oxidation 8, supply of fuel 9 from above and bottom of solid residue 10. A pipe for removing the residue from the main gas generator is connected to the afterburner.

 The main gas generator is equipped with a dehumidification system equipped with a fan 11 and a condenser 12, while the entrance to the system is connected via an inductor 13 to the upper zone of the shaft 5, and an outlet to the air supply pipe 8 for oxidation of the main gas generator.

 The output of the condensate and sludge from the condenser 12 is connected to the evaporator 14 connected on the heating side to the pipe 7 of the gas outlet from the main gas generator. At the same time, the outlet from the evaporator 14 from the heated side is connected via gas to the inlet to the fan 11 of the dehumidification system and via sludge to the ash removal device, to the container 4.

 To supply air for oxidation, the installation is equipped with a fan 15, at the discharge of which a heat exchanger 16 is installed, heated by the gas produced in the gas generators 1 and 3. The installation is also equipped with a gas purification system 17, which can be performed according to well-known technical solutions, for example, in nuclear power plants with VVER (see Chechetkin Yu.V. et al. "Purification of radioactive gaseous waste from nuclear power plants." M. Energoatomizdat, 1986, p. 56, Fig. 2.1).

 The inventive gas generator operates as follows.

 Wood radioactive waste of any moisture content, including logging residues and forest litter, is loaded into the hopper 2 and fed through the pipe 9 into the shaft 5 of the main gas generator 1. Before that, the main gas generator 1 is brought to the nominal mode, igniting it with prepared fuel and supplying air blast with using a fan 15.

 When loading waste with high humidity, the fan 11 is turned on and a part of the gas flow through the shaft 5 is taken through the choke 13. Depending on the humidity of the waste, the choke 13 sets the necessary flow of hot air and ensures stable quality of the generator gas.

 In the condenser 12, moisture, condensable resinous substances and fine particles trapped by the stream are separated from the gas and sent to the evaporator 14, and the gas with non-condensed moisture and volatile organic substances is sent via the fan 11 to the oxidation zone, mixing it with the air stream from the blower fan 15.

 In the evaporator 14, which is heated by the generator gas exiting through the nozzle 7 of the main stage, the liquid discharged from the condenser is divided into an evaporated part, which is mixed with the stream directed to the oxidation air supply nozzle and the residue in the form of sludge. To reduce the entrainment of radioactive contaminants trapped in the condenser 12, again into the zone of production of the generator gas, the evaporator 14 is of the volume type, and to increase the efficiency of evaporation, the gas output from the heated side is connected to the inlet to the fan 11.

 Thus, with increased humidity of the initial fuel in the condenser 12, an increased amount of liquid is obtained, which traps and carries out to the evaporator 14 the main amount of radioactive contaminants passing through the throttle 13 with the flow selected for drying, and due to the heat generated by the gas generator, most of the liquid in the form of steam purified from contaminants, it enters the working area of the gas generator, increasing the quality of the generator gas. The sludge along with radioactive contamination is fed directly into the container 4, where they are mixed with ash.

A feature of wood pollution as a result of the Chernobyl disaster is the predominance of cesium and strontium radionuclides related to substances that, at temperatures in the working zone of the gas generator, are sublimated and carried away with the generator gas to the gas treatment system 17. At the same time, these pollution in various forms of existence are concentrated in the surface layers of wood and with its increased humidity easily pass into the flow of the drying gas discharged through the inductor 13. The presence of a moisture removal system and discharge of sludge in its evaporator 14 of the container 4, passing the gas generators 1 and zone 3 to a temperature above 800 ^o C to reduce the load on the gas purification system 17, it is critical in ensuring the safety of work.

 Thus, the inventive gas generator, in contrast to the prototype, can reduce the possibility of contamination of the generator gas with radioactive substances during wood processing in areas contaminated during the Chernobyl accident, which with a large amount of wood waste to be processed will significantly increase the safety of such work.

Claims (1)

 A gas generator for processing wood radioactive waste containing a main gas generator and an afterburner, the main gas generator having a waste processing shaft, a grate, nozzles for exhausting the generator gas, for supplying air for oxidation, for supplying waste from above and for removing solid residue from below, this pipe for discharging solid residue is connected to a gas burner equipped with a device for removing ash, characterized in that the main gas generator is equipped with cleaning unit, including a condenser and a fan, arranged in series along the gas flow, while the system input is connected through the throttle device to the upper zone of the mine, the outlet to the pipe for supplying oxidation air, and the condenser and sludge outlet is connected to the evaporator connected on the heating side to the pipe for exhausting gas from the main gas generator, the outlet of the evaporator on the heated side by gas is connected to the inlet to the fan, and the outlet through slurries with a device for removing ash.