RU2193002C2 - Method of storing noncombusted fuel remnants in ash disposal area - Google Patents

Abstract

FIELD: handling of noncombusted fuel remnants. SUBSTANCE: method comes to putting remnants of fuel in wet state in ash disposal area and consolidating them using heavy tamper applying jarring strokes to surface of fuel remnants by heavy tamper are exposed to jarring by action of pulse pressure source dipped into fuel remnants. Treatment of fuel remnants and their consolidation are carried out at intensity providing excitation of acoustic cavitation in pore liquid, and solution formed in pores at acoustic in base of ash disposal area is entrapped and brought out of base of ash disposal area. Either internal vibrator generating jarring vibration in fuel remnants or charges of explosive generating jarring explosions or electric discharge device providing electric discharges in remnants of fuel can be as sources of pulse pressure. Solution entrapped in base of ash disposal area is directed for reprocessing for extraction of valuable components and for neutralization. Bubble acoustic cavitation provides dissolving of chemical elements and their compounds in remnants of fuel. EFFECT: provision of ecological safety at storing fuel remnants. 7 cl, 2 dwg

Description

 The invention relates to the field of construction and environmental protection, namely to harmless and economical storage in the ash dump of unburned fuel residues of thermal power plants.

 There is a method of storing unburned fuel residues (ash and / or slag, usually called ash and slag) in the ash dump by placing them in the form of pulp in the alluvial ash dump or in dry form in a bulk ash dump (Hydraulic Engineering Structures. Designer Guide. / Edited by V.P. Nedrigi .-- M .: Stroyizdat, 1983, p. 513).

 The disadvantage of this method is the irrational use of the land fund and the impossibility of building a filled ash dump due to the low strength and high deformability of the remaining fuel in the ash dump.

 There is a method of storing unburned fuel residues in the ash dump, including placing wet fuel residues in the ash dump and treating (compaction) them with shocking sources of pulse pressure placed to a depth in fuel residues, such as deep vibrators or explosive charges (O. Minaev P. The prospect of using dynamic compaction when laying ash and slag materials and preparing the base for ash dumps - Hydrotechnical construction, 1995, 12, p. 27-31).

 The disadvantage of this method is the insufficient degree of compaction of fuel residues, especially at their surface, as well as the unevenness of their compaction at depth.

 There is also known a method for storing unburned fuel residues in the ash dump, including placing wet fuel residues in the ash dump and compacting them with a heavy rammer, producing shocking tamper shocks on the surface of the fuel residues.

 The disadvantages of this method of storing unburned fuel residues in the ash dump are: firstly, the insufficient degree of compaction of fuel residues, especially at a depth, and the small area of involvement of fuel residues in the compaction process when impacted by tamping (depth, radius of action) due to the large part of the impact energy is spent on destroying the structure of fuel residues and on converting loose-bound pore moisture into free, secondly, low environmental safety due to the fact that during shocking tamper impacts Both the dissolution of the chemical elements and compounds in the fuel residues in pore moisture and the release of this moisture from the compacted fuel residues, which pollutes groundwater, and thirdly, the low economic performance of the method due to the fact that irreversible losses of expensive rare and scattered elements, such as germanium and galium, dissolved in moisture.

 The problem to which the invention is directed, is to increase the economic efficiency and environmental safety of storage in the ash dump of unburned fuel residues. The technical result from the use of the invention is to increase the degree of compaction of fuel residues, to prevent pollution of groundwater and to extract valuable components from the fuel residues.

 The problem is solved, and the technical result is achieved by the fact that in the method of storage in the ash dump of unburned fuel residues, including placing in the ash dump fuel residues in a wet state and compacting them with a heavy rammer, producing shocking shocks on the surface of the fuel residues, according to the invention immediately before compaction of the residues heavy tamper fuels they are treated with shocking impacts of a source of impulse pressure placed at a depth of residual fuel, while the processing of fuel residues and their compaction is carried out with an intensity that provides excitation of acoustic cavitation in the pore fluid, and the solution formed in the pores of the fuel residues as a result of acoustic cavitation and released from the fuel residues during processing and compaction is captured at the base of the ash dump, and divert this solution beyond the base of the ash dump. As a source of pulsed pressure, a deep vibrator is used, which produces vibrating vibrations in the fuel residues, explosive charges, vibrating explosions in the fuel residues, and an electric-discharge device producing shocking electric discharges in the fuel residues. Additionally, the solution is captured by means of solution-receiving elements located in the base of the middle part of the ash dump below the groundwater level along its perimeter, and the solution is discharged through the pipeline by means of a pump with an intensity that ensures the formation of a depression funnel at the base that contains the entire ash dump in the plan. It is advisable to saturate the remaining fuel with a leach solution before processing and / or compaction, and valuable components can be removed from the solution trapped in the base of the ash dump.

 The essence of the technical solution lies primarily in the fact that before compaction of wet fuel residues with a heavy rammer, they are treated with shock waves of a pulse pressure source, and during the processing of fuel residues and during their compaction in a pore liquid, bubble acoustic cavitation is stimulated, which anomalously intensifies the dissolution of chemical elements and their compounds that make up the remainder of the fuel. After that, the solution formed and separated from the fuel residues during their processing and compaction is captured at the base of the ash dump and valuable components are extracted from it, if economically feasible.

 The implementation of the method of storage in the ash dump of unburned fuel residues is illustrated by the drawings: Fig. 1 shows an example of a plain ash dump, at the final stage of filling of which a transition is made from hydraulic storage to bulk, cross section; figure 2 is an example of a quarry bulk ash dump, which carry out the re-storage of fuel residues from the operational dump, cross section.

 Example 1. When storing ash and slag 1 in a flat ash dump (Fig. 1), the upper surface 2 of which did not reach its final set level 3, and the increased environmental requirements do not allow further hydraulic storage of ash and slag, they switch from hydraulic storage to bulk.

 First, the settling pond 4 is drained in the ash dump (alluvium map), and water wells 6 are carried out from the surface of its bottom 5 in the middle part of the ash dump, water inlets (mud receivers) 7 of which are located below groundwater level 8 along the perimeter of the ash dump. After that, from the surface of the ash dump 2 deep compaction of ash and slag 1 and partially of the soil of the base 9 is carried out at a high degree of water. The compaction is carried out by heavy tamper 10, which produces shocking tamper shocks on the surface of ash and slag 1, which excite acoustic cavitation in pore water of ash and slag 1. Immediately before the impacts of tamper 10 on ash and slag 1, located in the plan near the crater 11 - the location of the impact of tamper 10, they are driven by deep vibrators (vibration rods) 12, which carry out vibration with intensity, which ensures formation of ash zones 1 around vibrators 12 with acoustic cavitation in pore water .

With such intensive vibration processing, the ash and slag structure is destroyed as a result of cavitation bubbles, and the following physicochemical transformations occur in pore ash and slag water: first, loose-bound water temporarily passes into free water, and viscosity decreases in all free water, and secondly, peroxide forms hydrogen Н ₂ О ₂ with its subsequent decay in the form of microexplosions into Н ₂ О and O.

The first transformation leads to a temporary increase in the permeability of ash and slag and thus the formation of drainage zones 13, and the second to a temporary decrease in the volume of liquid in the pores of ash and slag and the pressure of gases in them (density of hydrogen peroxide at zero temperature 1.47 g / cm ³ ).

 After such preparation of ash and slag, which directionally changed the properties of the skeleton of ash and slag (the structure is destroyed) and the properties of pore water (the water is “liquefied”, and its volume has decreased), the compaction process by tamping proceeds very efficiently and is also accompanied by the previously indicated useful physicochemical transformations, more intensively and in a larger volume than when tamping without vibration processing of ash and slag 1 (RU 2149238 C1, 05.20.2000).

 Simultaneously with the compaction of ash and slag 1 under the action of the formed active atomic oxygen, vigorous oxidation of the hardly soluble ash and slag components occurs, which pass into the water in the form of soluble compounds, resulting in intensive neutralization of ash and slag with the formation of a highly concentrated solution in their pores. By timely activation of water wells 6, this solution released from ash and slag during vibration processing and compaction by tamping is captured by water receivers 7 and, by means of pump 14, is discharged outside pipeline 9 to the base of ash dump to neutralize them, moreover, it is discharged with an intensity ensuring depressive formation in base 9 funnel 16, containing in plan the entire ash dump and having a near-zero slope of the surface of groundwater around the perimeter of the ash dump. Thus, the formation of a spreading solution under the ash dome is prevented, which is monitored by observation wells 17. All this prevents the pollution of groundwater.

 The final stage of filling the ash dump from the level 18 to the final level 3 newly obtained in the process of compaction of ash and slag is carried out similarly to that described or in layers with compaction by vibratory rollers. After that, the ash dump with neutralized ash and slag canned with reclamation of its surface, and if necessary, built up.

 Example 2. The bulk ash dump (figure 2) is located in a spent rock quarry 20, the bottom 21 of which is sloped and waterproofed with a layer of loam 22, covered with a drainage layer (coarse sand) 23, which is connected via a discharge pipe 24 to the sump (grout, not shown). In such an ash dump by means of vehicles, wet ash and slag 25 are re-sorted from an operational dump (hydraulic dump is not shown; such ash and slag re-sorting is carried out at Krasnoyarsk TPP-2).

 After filling the ash dump to an intermediate level 26 by means of perforated pipes 27, the ash and slag 25 are saturated with a leach solution 28. At the same time, wells 29 are executed in a predetermined order and at a given depth, and each time a spark gap 30 is lowered into the cavity of the well 29, connected by an electrical conductor 31 to the electric discharge unit 32 and well 29 is filled with water-saturated ash and slag. After that, a series of camouflage shocking electric discharges are produced in well 29. After all this, the sections of ash and slag treated with electric discharges are compacted by shocking tamper shocks of heavy rammer 33 with the formation of craters 34 - the place of impact of the rammer.

An electric discharge forms a plasma channel, which leads to the breaking of chemical bonds in ash and slag and to the formation of new compounds. This forms the anion OH ^-, which intensively proceeds at a hydrogen peroxide H ₂ O _2. The latter decomposes in the form of microexplosions into H ₂ O and O, which causes energetic and almost instantaneous oxidation of the previously insoluble and hardly soluble chemical compounds of ash and slag formed by active atomic oxygen 25. At the same time, high pulsed pressure creates shock waves, which cause, in a more significant, comparison with a plasma channel, volume 35, acoustic cavitation in a saturating ash and slag solution, which leads to compaction of ash and slag, as well as to physicochemical analogous to that in the plasma channel their transformations. At the same time, the current level of knowledge suggests that during electric discharge processing of ash and slag due to transmutation of nuclei, useful transformations of some elements to others occur, and, perhaps, in the entire cavitation volume 35 (L. Nikitsky. “Pure Gold.” Newspaper “Moscow News”, 29, 2000).

 After processing the ash and slag by electrodischarge shocks, accompanied by uneven, with the formation of dips, deep compaction of ash and slag, the ash and slag compaction is very efficiently compacted, which is also accompanied by acoustic cavitation and the previously mentioned physicochemical transformations, more intensively and in a larger volume than when tamping without electrodischarge ash handling 25.

 The productive solution formed during the intensive leaching of ash and slag under the influence of shocking electric discharges and tamping is intensively separated from the ash and slag during the compaction process, enters the drainage layer 23 and is discharged through a pipe 24 to a sump (not shown), from where it is taken for processing for extraction from valuable components and its neutralization.

 Explosive charges can be placed in boreholes 29 similar to those described in boreholes, and aeoloslags can be processed with shocking explosions before compaction.

 The final stage of filling the ash dump from the level 36 newly obtained in the process of compaction of ash and slag to the final level 37 is carried out similarly to that described or in layers with compaction of vibratory rollers. After that, the ash dump with neutralized ash and slag canned with reclamation of its surface, and if necessary, built up.

Using the invention will simultaneously solve three problems:
- to increase the uniformity and degree of compaction of unburned fuel residues by tamping due to their preliminary deep processing by a vibrating rod, explosive charges or electric dischargers and thus to further increase the useful volume of the ash dump (up to 40 percent compared to stacking fuel residues in a hydro-mechanized way and up to 30 percent compared with compaction by their static effect by mechanisms) and better prepare the ash dump for development;
- increase the environmental safety of the ash dump by more fully preventing the pollution of groundwater both by trapping contaminants directly during compaction of fuel residues and by burying them in a neutralized state;
- to improve the economic performance of the method of storage in the ash dump of fuel residues due to the extraction of valuable components from them.

Claims (7)

 1. A method of storing non-combustible fuel residues in the ash dump, including placing wet fuel residues in the ash dump and compacting them with a heavy rammer, producing shocking tamper shocks on the surface of the residual fuel, characterized in that they are treated with shocking impacts of the source immediately before the fuel residues are compacted by heavy ramming pulse pressure placed to a depth in the fuel residues, while the processing of fuel residues and their compaction is carried out with ensivnostyu providing excitation in the pore fluid of acoustic cavitation and in the bottom ash disposal catch solution in the pores formed in the residual fuel resulting acoustic cavitation and released from the fuel during their processing residues and seal, and this solution is withdrawn beyond the base of the ash dump.  2. The method according to claim 1, characterized in that a depth vibrator is used as a source of pulsed pressure, producing vibrating vibrations in the fuel residues.  3. The method according to claim 1, characterized in that explosive charges are used as a source of pulsed pressure, producing shocking explosions in the fuel residues.  4. The method according to p. 1, characterized in that an electric discharge device is used as a source of pulsed pressure, which produces shocking electric discharges in the fuel residues by means of an electric discharge.  5. The method according to p. 1, characterized in that the solution is caught by means of solution-receiving elements located in the base of the middle part of the ash dump below the groundwater level along its perimeter, and the solution is discharged through the pipeline through a pump with an intensity that forms a depression funnel at the base, containing in plan the entire ash dump.  6. The method according to p. 1, characterized in that before processing and / or compaction, the remaining fuel is saturated with a leach solution.  7. The method according to p. 1, characterized in that the solution collected at the base of the ash dump is sent for processing to extract valuable components from it and to neutralize it.

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