RU2278205C1 - Method for filing ash dump erection in permafrost zone - Google Patents

Abstract

FIELD: hydraulic building, particularly to erect ash dumps.

SUBSTANCE: method involves forming primary dam of ground; filling sections with ash in several layers and freezing thereof in cold season; discharging drain liquid including rain water and contaminated liquid from sections to water accumulation tank in warm season, wherein the water accumulation tank is created within section area and has bottom mark increasing during ash backfilling; forming inclination in outer layer surface, which is directed towards water accumulation tank; depressing dust with water in warm season, wherein water for dust depression is taken from water accumulation tank and is supplied at rate, which provides distribution of at least half of tank volume till cold season.

EFFECT: increased efficiency of ash dump erection and improved environmental protection.

7 cl, 4 dwg, 2 ex

Description

The invention relates to hydraulic engineering, in particular to the construction of bulk ash and slag dumps in the permafrost distribution zone.

There is a known method of erecting ash and slag dump, in which the specified height of the ash and slag build-up height ensures the accumulation of all atmospheric precipitation moisture and dust suppression due to the "freely held" equilibrium ash and slag moisture W _max , that is, only due to the "drainless" increase in ash and slag moisture (A. S. USSR No. 1792462, IPC E 02 B 7/06, publ. 30.01.93).

Humidity W _max in ash and slag usually does not exceed a value of 0.4, which provides a degree of humidity (the ratio of water volume to pore volume in a unit volume of ash and slag) G of about 0.3, therefore, most of the pore volume remains unfilled with water, which leads to a high build rate such a "drainless" ash dump. In the Northern construction and climatic zone, during long cold seasons, solid precipitation (snow) is layer by layer preserved in freezing ash and slag, which leads to unproductive use of ash and slag dump tanks, and in the warm season, especially in spring, contaminated runoff from the frozen ash and slag surface worsens the environmental condition of the surrounding Wednesday.

Closest to the proposed method is the construction of a bulk ash and slag dump in the permafrost propagation zone, including the erection of a primary dam from the soil, tier dumping of ash and slag into sections and their freezing naturally in the cold season, discharge of ash and slag from the ash dump into the drainage tank of wastes generated from sediments and contaminated in the filled section in the warm season and the creation of an ash dump on the outer slope above the crest of the primary dam of the restoration layer. At the same time, the entire dam area is fenced with a primary dam, which is separated by water-permeable inner dams into sections with the annual ash and slag storage volume, and all contaminated water in the storage section is discharged sequentially through unfilled sections (AS USSR No. 1693178, IPC E 02 B 7/06 publ. 11/23/91).

In this method, as in the previous one, when ash and slag are poured in the cold season, sediments do not fill the pores in the ash and slag, but they are canned in layers. When the contaminated runoff from the filled section is removed during the warm season, it is mixed with the clean runoff of unfilled sections, which increases the volume of the catchment tank, the creation of which outside the ash and slag dump is associated with the complication of work, increased costs and occupied areas. Moreover, the spillway capacity itself can become a source of environmental pollution.

The objective of the invention is the accumulation in pores of ash and slag of all precipitation contaminated during the construction of bulk ash and slag frozen and ensuring its "drainage", which increases the efficiency of the construction of bulk ash and slag frozen by simplifying operations, reducing costs, reducing footprint and improving environmental environmental conditions.

The problem is solved in that in the method of erecting a bulk ash and slag dump in the permafrost distribution zone, including erecting a primary dam from the soil, tiered ash and slag dumping in sections and freezing them naturally in the cold season and discharging wastewater from sediments and polluted into the catchment tank in the section, in the warm season, according to the invention, a spillway tank is created within the section area and with a bottom mark that increases during the dumping of ash and slag into the tier, and the outer the surface of the tier gives a bias towards the spillway. In the warm season, dust suppression is carried out in the section with water taken from the spillway tank and with an intensity that ensures at least a half-empty state of the spillway tank at the beginning of the cold season.

In addition, ash and slag are dumped immediately to the full height of the tier, while the volume of ash and slag in the tier is equal to their annual volume of dumping, and the tier height h _I satisfies the condition

where q _and is the estimated annual precipitation to be accumulated in the ash and slag section;

n is the estimated porosity of ash and slag in the tier;

G _I - the estimated degree of humidity of ash and slag in a completely filled layer after taking in the estimated annual atmospheric precipitation q _and ;

G _n - the initial degree of moisture ash and ash at their estimated initial moisture content before dumping and at their estimated porosity n in the tier.

In addition, a spillway capacity is created in the middle part of the section area between a part of the tier dumped in the cold season and a part of the tier dumped in the warm season. A part of the tier dumped in the cold season is placed over the same part of the previous tier and it is poured in plan in the same sequence, while the outer surface of each tier is covered with a layer of filtering soil or soil-like material, which is directly adjacent to the water intake tank. At the same time as ash and slag are poured into the tier, filter material is at least discretely poured into the water intake tank, moreover, ahead of the rising bottom of this tank.

When dumping ash and slag into a longline, it is advisable to move the snow located in front of the end of the longline, moreover, the contaminated snow should be transported to the water receiving tank, and the clean snow to the external slope of the secondary dam. If necessary, ash and slag are poured into the layer in layers.

The proposed method for storing ash and slag waste allows the filling of frozen ash and slag dump pits to fill the pores of ash and slag with freezing water more fully than filling pores with water in a thawed ash and slag dump only due to the freely held moisture content W _max , and thus construct a drainless ash and slag dump with a relatively high growth rate .

Figure 1 shows a plain ash dump, plan; figure 2 is a section aa in figure 1; figure 3 - ravine and beam ash and slag dump, plan; figure 4 is a section bB in figure 3. In figure 2 and figure 4, the degree of reduction of horizontal dimensions is 2 times greater than the degree of reduction of vertical dimensions.

The method is implemented as follows.

Example 1 (figure 1 and figure 2).

The bulk ash and slag dump of the flat type on the frozen base 1 is erected by sequentially filling the ash and slag 2 of section 3. First, a primary dam 4 of the frozen type is erected from the soil along the perimeter of section 3, which forms a container for storing the first tier 5 of ash and slag. A container for each subsequent tier is created by erecting secondary dams from the soil 6. When erecting the primary dam 4, base soil 1 is used to form a recess 7 in the middle of section 3, which forms the lower part of the drainage tank 8. Ash and slag 2 is poured into tier 5 with their freezing naturally in the cold season and immediately to its full height according to the “downhill” scheme, while the volume of ash and slag in tier 5 is equal to their annual volume of dumping in section 3. In each tier 5 in the middle of the section 3 over the recess 7 me Part 9 of tier 5, covered in the cold season (same: the winter part of the tier), and part 10 of tier 5, covered in the warm season (the same: the summer part of the tier), by non-closure of these parts of the tier create a spillway 8, bottom mark 11 which in the process of dumping ash and slag is increased by filling the drainage tank 8 ash and slag. The outer surface of tiers 5 is biased towards the catchment tank 8. In the warm season, this ensures the discharge of wastes generated from liquid and winter solid precipitation and contaminated in the section to the catchment tank 8 and the use of these drains for dust suppression in the section mainly over the summer part 10 tiers (water supplies not shown). Dust suppression with water is carried out with an intensity that provides at least a semi-empty state of the catchment tank 8 at the beginning of the cold season.

The section area is assigned from the condition that, for a given annual volume of dumping in the ash and slag section, the tier height h _i , and therefore the section building speed in height, would satisfy the above condition:

The winter part 9 of the tier is placed over the same part 9 of the previous tier and dumped in the plan in the same sequence. The latter provides relatively uniform freezing over the entire area of this part of the tier.

The outer surface of each tier 5 is protected from wind and water erosion by a layer 12, which is usually made of a thickness of not more than 0.05-0.1 meters from filter soil or slag and adjoins it to the water receiving tank 8. At the same time as ash and slag is poured into tier 5 into the water receiving the filter container 8 is discretely and ahead of the rising bottom 11 of this container filter material is poured, thus forming a filter channel 13, which provides a hydraulic connection of the filter layers 12 with a spillway container 8. The latter substantially contributes to a spread of sewage water discharge vessel 8 in the whole volume backfilled section 3 of ash. This is also facilitated by the fact that with a tier height of 1.5-2.0 meters or more at the bottom of the tier, usually a temporary melt layer is preserved.

When ash and slag are poured into the winter part of the 9th tier, the snow located in front of the end of the tier is moved, while the contaminated snow is transferred to the spillway 8, and pure snow (if necessary) is transferred to the external slope of the secondary dam 6. The first prevents the snow layer from being buried in the ash and slag, and the second decreases the estimated annual precipitation q _and . The winter part of the 9th tier can be poured in layers. This ensures its high-quality freezing, but at the same time dust suppression is complicated.

Primary dam 4 and secondary dams 6 are usually erected in the warm season, followed by freezing them in the cold season. These dams rise to the ground with ash and slag and prevent the outflow of polluted effluents from the section, as well as reduce the removal of wind erosion products from the section, including in the form of contaminated snow. At the same time, dams 4 and 6 protect the external slope from wind and water erosion and perform the functions of a remediation layer.

The entrance to the section 3 is carried out through the ramp 14, which, as the section 3 is filled, is tiered up. After filling the upper (fifth) tier 15, the ash and slag surface is planned and protected by a remediation layer 16. Over time, the entire section 3 in the permafrost distribution zone acquires the state of the permafrost massif.

Further dumping of ash and slag is carried out in the subsequent section 17, adjacent to the filled. When this drainage tank 8 can be directly adjacent to the outer slope of the filled section.

As an example, let us determine the height of the “annual” tier h _i according to the above inequality with the following parameters: q _and = 0.4 meters; n is 0.6; G _i = 0.5; G _n = 0.1

In the North-Eastern regions of Russia, the average annual rainfall is usually less than 0.4 meters. Therefore, the construction of a closed dry bulk ash and slag dump of frozen type (average annual temperatures are negative) in these areas is feasible. When freezing ash and slag, moisture redistribution constantly occurs in them. Therefore, compliance with the totality of the actions provided by the proposed method, will saturate ash and slag with effluents to the value of their degree of humidity G _i = 0.6-0.7 and, thus, carry out the construction of a waste-free ash and slag dump at an annual rainfall of 0.6-0.7 meters and more. Moreover, the burial in a limited amount of precipitation in the form of ice and snow, mainly within the spillway capacity, does not worsen the proposed method.

Example 2 (figure 3 and figure 4).

A bulk ash and slag dump in the ravine-beam lowering of the relief is erected similarly to the described plain. In this case, sections 3 are placed sequentially from the top of the lowering (ravine) to its mouth. The construction of the ash and slag dump begins with the construction of a non-filtering frozen water-lifting dam 18, equipped with temporary freezing columns 19 and blocking the lowering at its top, and drainage ditches 20 in the lowering sides 21. The capacity for the first leveling tier 22 of ash and slag is created by erecting a primary dam 4, blocking the lowering at a distance towards the mouth of the lowering from the water intake dam 18, and under the upper tiers by erecting secondary dams 6. The water receiving tank 8 in section 3 is combined with the thalweg 23 lowering, and in the leveling tier 22 the ash and slag is sprinkled with layers 24 (shown by a dotted line).

Claims (7)

1. A method of erecting a bulk ash and slag dump in the permafrost propagation zone, including erecting a primary dam from the soil, tiering ash and slag into sections and freezing them naturally in the cold season, and draining wastewater from sediments and polluted in the section into the catchment tank to warm time of year, characterized in that the catchment is created within the section area and with a bottom mark that increases during the dumping of ash and slag into the tier, and give the slope to the side of the outer surface of the tier a catchment tank, while in the warm season, the sections carry out dust suppression with water taken from the catchment tank with an intensity that provides at least a half-empty state of the catchment tank at the beginning of the cold season. 2. The method according to claim 1, characterized in that the ash and slag is dumped immediately to the full height of the tier, while the ash and slag volume in the tier is equal to their annual dumping volume, and the tier height h _I satisfies the condition

where q _u is the estimated annual precipitation to be accumulated in the ash and slag section; n is the estimated porosity of ash and slag in the tier; G _I - the estimated degree of humidity of ash and slag in a completely filled layer after receiving the estimated annual atmospheric precipitation q _u ; G _n - the initial degree of moisture ash and ash at their estimated initial moisture content before dumping and at their estimated porosity n in the tier. 3. The method according to claim 1, characterized in that the drainage tank is created in the middle part of the section area between the part of the tier dumped in the cold season and the part of the tier dumped in the warm season. 4. The method according to claim 1, characterized in that the part of the tier to be dug in the cold season is placed over the same part of the previous tier and dumped in plan in the same sequence, while the outer surface of each tier is covered with a layer of filtering soil or soil-like material which directly adjoins the catchment tank. 5. The method according to claim 1, characterized in that at least a discretely filtering material is poured into the catchment tank, moreover, ahead of the rising bottom of this tank. 6. The method according to claim 1 or 4, characterized in that when dumping the ash and slag into the tier, the snow located in front of the end of the tier is moved, the contaminated to the drainage tank, and clean to the external slope of the secondary dam. 7. The method according to claim 1, characterized in that the dumping of ash and slag into the tier is carried out in layers.

Images