DE3824078C1 - Process for solidifying water-soluble special wastes - Google Patents

Abstract

In the solidification of special wastes from flue gas purification plants, which special wastes contain water-soluble and hygroscopic materials, by means of hydraulic binders, highly leaching-resistant landfill bodies are obtained if the necessary amounts of hydraulic binders (Z) and water (W) are determined by the following equations: <IMAGE> in which R = the amount of special wastes in the end product Rw = the amount of the water-soluble portion of the special wastes in the end product WZ = the amount of water necessary for the hydraulic binder WRw = the amount of water necessary for the water-soluble portions of the special wastes in the end product CH = concentration of the hygroscopic portion of the special wastes (all in per cent by weight).

Description

The invention relates to a method of consolidation of hazardous waste from flue gas cleaning systems that contain water-soluble and hygroscopic substances Mixing with hydraulic binders, water and if necessary additives to improve the setting behavior, like sodium sulfide, to crack-free landfill bodies low, defined leaching rates.

A large number of hazardous waste with proportions of large Water solubility, for example salts and salt mixtures, from flue gas cleaning, some of which are toxic Heavy metals that are contaminated must be sent to hazardous waste landfills be deposited, as a material recycling is usually not possible. A deposit this waste in hazardous waste landfills without conditioning and without immobilizing the pollutants, for For example in plastic bags, in barrels or in cassettes made of clay, is not a satisfactory solution since one absolute water closure not feasible and a Ingress of water cannot be ruled out. The soluble ones Components of the waste are then removed in short periods of time discharged via the seepage water. Without collection and subsequent costly post-treatment of the Leachate is a threat to surface water and to be expected from groundwater.

Contains hazardous waste from flue gas cleaning systems usually also hygroscopic components, mostly in the form of calcium chloride.

There is therefore an effort to avoid these dangers avoid. The first and foremost problem solution is one Conditioning of the hazardous waste via solidification in question that a release of the pollutants for long Periods largely prevented and with leaching only leads to eluate concentrations below the legal limit values for direct discharge in surface water or on the order of the natural contents in the groundwater.

In order to ensure such safe landfilling of To be able to guarantee water-soluble waste must the product to be disposed of (landfill body) is as follows The main requirements are:

• a) Immobilization of pollutants, that is, large Resistance to leaching and, if any, one controlled release of pollutants.
• b) Aging resistance, that is, mechanical and chemical integrity of the final product must be in short Reached in time and maintained over a long period of time.
• c) Economy, that is, large loads of waste in the end product and simple process concept.

In the field of conditioning respectively Solidification of hazardous waste are a variety of Process known and in some cases practically in use. Cement, for example, serve as conditioning agents, Water glass, pozzolan, lime, gypsum or organic polymers. The conditioning largely more water-soluble Hazardous waste in cement is practically not used, because the hazardous waste content in the cement product in these Cases by the impairment the setting and setting behavior to relatively low Values is limited.

In DD-PS 1 49 136 a method for off and Disposal for a large number of wastes described, which are predominantly of mineral origin, low Have water solubility and almost always contain cement-compatible substances. This waste are simply hardened with chemical reaction or thermoplastic molten binders such as Cement, lime, gypsum or bitumen, mixed and in the Landfill room introduced. Special measures to increase the leaching resistance or the aging resistance are not hit.

In DE-OS 34 26 800 is with the production of sealed spherical salt / cement bodies that are in embedded in a salt-free cement matrix Procedure demonstrated, in addition to a high salt load up to 50 wt .-% in the end product for a barrier system Reduction of leachability and increase in Has leach resistance. Disadvantage of this procedure is that to build the barrier system several Procedural steps must be carried out that are both in investment and operating costs knock down.

In the patent application DE-OS 35 45 592 a method for the conditioning of water-soluble hazardous waste by adding cement, water and additives described in which the landfill body in individual Layers made and a vertical as well as a horizontal one Salt concentration gradient from 0 to 70% with maximum Salt content in the middle of the body and a hazardous waste-free Edge layer is set.

Disadvantages of this method are the use of a complicated device as well as the high salt concentrations if the water / cement values in the middle of the body are also high, resulting in poor mechanical stability lead and thus the risk of breakage of the landfill body raise.

From DE-OS 35 18 411 a method for landfilling is of flue gas desulphurisation products known in which these with pozzolanically active fly ash, calcium hydroxide and water is solidified.

A major disadvantage with all known methods with hydraulic binders results from the fact that it is not possible to mix the proportions of water and hydraulic binder to be set so that on the one hand with certainty an uncontrolled leaching of water-soluble salts are avoided (too high water Cement value), on the other hand one destroying the Crack formation leading to the landfill is definitely excluded (water-cement value too low).

It was therefore an object of the present invention to provide a Process for the solidification of hazardous waste Develop flue gas cleaning systems that are water-soluble and contain hygroscopic substances Mixing with hydraulic binders, water and if necessary additives to improve the setting behavior, like sodium sulfide, to crack-free landfill bodies low, defined leaching rates, whereby by precalculation the necessary quantities of hydraulic binders and water the lowest possible leaching rates and As few cracks as possible should be made in the landfill body.

This object is achieved according to the invention in that the necessary amounts of hydraulic binders (Z) and water (W) are determined in percent by weight according to the following equations:

with the following boundary conditions:

a) 40 R 70
b) 0 < R _w 35
c) 3.1 A 4.1
d) 0.12 B 0.16
e) 0 < C _H 25
f) (AB * C _H ) <0

whereby

R = amount of hazardous waste in the end product R _w = amount of the water-soluble portion of hazardous waste in the end product
W _z = amount of water required for the hydraulic binder
W _RW = amount of water required for the water-soluble components of hazardous waste in the end product
C _H = concentration of the hygroscopic portion of hazardous waste

(all in percent by weight) means.

If cement is used as the hydraulic binding agent, values between 0.3 and 0.4 are preferably chosen for the constant W _z / Z, and a value of 0.3 if Portland cement is used.

Extensive investigations with different Have hazardous waste from flue gas cleaning systems showed that, as has been the case up to now, the water Cement value (i.e. the ratio between im End product available water and cement) for the The quality of the landfill body is a decisive parameter, but an additional specific amount of water that on the water-soluble portion in hazardous waste must be taken into account.

The amount of hazardous waste (R) that can be introduced into the end product must be determined empirically and is between 40 and 70% depending on the type of hazardous waste. The constants A and B must also be determined empirically through experiments, the hygroscopic portion of hazardous waste including the salts that accumulate water before dissolution, for example as water of crystallization. The hazardous waste must therefore be analyzed before conditioning.

According to this selection rule for the for a certain amount of hazardous waste containing water-soluble compounds required quantities of hydraulic binders and water, based on consolidation tests on different water-soluble hazardous waste, such as flue gas cleaning residues (Salts, salt / fly ash mixtures) from one Hazardous waste incineration plant (wet, waste water-free Laundry) and from various waste incineration plants (wet, wastewater-free laundry as well as dry laundry) has been checked can be traced with a continuously operated mixing plant, consisting of storage container and metering devices for the solids involved as well as a suitable one continuous mixing device manufacture landfill bodies, which are characterized by extremely low, over diffusion coefficients predictable leaching rates for chlorides and all heavy metals and one for surface landfill very good mechanical stability.

The following examples are intended to illustrate the process according to the invention explain in more detail:

• 1. Hazardous waste from a flue gas cleaning system is conditioned which contains 36% by weight of water-soluble content, including 23% by weight of hygroscopic content in the form of calcium chloride. It has been empirically found that good landfill bodies can be obtained with a proportion of this hazardous waste of 50% by weight in the end product. Portland cement is used as a conditioning agent. This results in: R = 50, R _w = 18, C _H = 23, The constants A and B were determined from equation (2) for Portland cement by experiments: A = 3.5 and B = 0.15. The required amount of cement and water can be calculated from equations (1) to (4): Z = 37% by weight, W = 13% by weight, R = 50% by weight If 740 g of Portland cement and 260 g of water are mixed in per kilogram of this hazardous waste, landfill bodies are obtained that are extremely resistant to leaching and crack-free.
• 2. According to example 1, hazardous waste is conditioned with R = 50, R _w = 18 and C _H = 23. With A = 3.64 and B = 0.14, Z = 31% and W = 19%.
• 3. According to example 1, hazardous waste is conditioned with R = 50, R _w = 14 and C _H = 18. With A = 3.64 and B = 0.14, Z = is calculated from equations (1) to (4) 25% and W = 25%.
• 4. According to example 1, hazardous waste is conditioned with R = 65, R _w = 13 and C _H = 19. With A = 3.64 and B = 0.14, Z = 17% and W = 18%.

The Z and W values calculated according to these examples resulted in landfill bodies which were extremely resistant to leaching and free from cracks.

A general calculation scheme results from the following table:

Tabel

Claims (3)

1. A process for solidifying hazardous waste from flue gas cleaning systems that contain water-soluble and hygroscopic substances, by mixing them with hydraulic binders, water and, if necessary, additives that improve the setting behavior, such as sodium sulfide, to crack-free landfill bodies with low, defined leaching rates, characterized in that the necessary quantities of hydraulic binders (Z) and water (W) can be determined in percent by weight according to the following equations: with the following boundary conditions: a) 40 R 70
b) 0 < R _w 35
c) 3.1 A 4.1
d) 0.12 B 0.16
e) 0 < C _H 25
f) (AB · C _H ) <0 where R = amount of hazardous waste in the end product
R _w = amount of the water-soluble part of the hazardous waste in the end product
W _z = amount of water required for the hydraulic binder
W _RW = amount of water required for the water-soluble components of hazardous waste in the end product
C _H = concentration of the hygroscopic proportion of hazardous waste (all in percent by weight). 2. The method according to claim 1, characterized in that when using cement as a hydraulic binder for the values between 0.3 and 0.4 can be selected for the constant. 3. The method according to claim 2, characterized, that when using portland cement for the equation (3) a value of 0.3 is chosen.