DE2206523A1 - Precipitating agents for purifying water and processes for making the same - Google Patents

Description

Precipitating agents for purifying water and methods of manufacture of this agent "Production of this agent" The invention relates to cleaning agents for purifying water and a method for producing such a precipitant.

The water to be cleaned can be raw water, i.e. that in the waterworks water introduced from reservoirs, e.g. lakes, rivers, groundwater, rainwater and the like. The cleaning can also relate to wastewater, in particular wastewater from localities or from industries etc.

The raw water is controlled by its pH and precipitation of dissolved salts and impurities are cleaned. The raw water should therefore be a water result, which is suitable e.g. as drinking water and for the preparation of meals and does not give rise to deposits in pipelines or process machines.

The wastewater should be cleaned in such a way that it can, without damage or disadvantages to bring, can be drained into the recipient.

The raw water contains iron, manganese, aluminum and various phosphates contain. In addition to these substances, the wastewater has an approx higher concentration than occurs in raw water, also a large number of organic ones Contain substances such as viruses and bacteria. The sewage can Besides that heavy metals, such as copper, lead and mercury, in relatively large quantities contain.

Compounds of iron, manganese and aluminum are usually chemical precipitated by the addition of aluminum sulfate and / or calcium oxide. The precipitation technique is in principle the same for raw water and wastewater. The precipitant will added in such an amount that the pH of the water stimulates the precipitation of iron, Manganese and aluminum favors while at the same time providing sufficient amounts of precipitant are present to precipitate impurities o When cleaning raw water approx. 50 g per m3 and approx. 500 g / m3 for the purification of wastewater are required.

A neutral or slightly alkaline raw water demands another Treatment as an acidic raw water, and in wastewater purification needs treatment adapted to the impurities that the wastewater contains.

In all flocculation, the precipitation is initiated that Microflakes are formed. These are then made to turn into macro flakes to join together The macro flakes should have such properties that adsorption and / or complex salt precipitation becomes as effective as possible.

The substances excreted by adsorption or complex salt precipitation include phosphates, heavy metals and residues from biological cleaning.

By supplying flake-forming and / or flake-promoting Substances can be converted into finely dispersed substances in such a way that they can be separated from the water.

This technique is very old.

The first stage of flake formation, i.e. the formation of microflakes, is called the coagulation stage by several researchers, while the second stage, the build-up of macro-flakes, is known as the flocculation stage will. The invention encompasses both of these stages.

Water purification is usually carried out in three stages. The first Stage concerns mechanical sedimentation of coarse waste. In the second In the 2nd stage (biological cleaning), the organic substances contained in the first stage have not sedimented or are dissolved in the water. In the third stage (chemical cleaning) substances formed in the biological stage, Nutrient salts as well as iron, manganese, aluminum and heavy metals are precipitated.

There are also three chemical precipitation methods10 Direct Precipitation or pre-precipitation means that the precipitating agent during the first stage is added, simultaneous precipitation means that the precipitating agent during the biological cleaning is added and post-precipitation means that the precipitating agent is added during the third stage.

A majority of the known precipitants, mostly salts of Iron and aluminum, require that the flocculation be at a relatively certain level pH takes place. Lime in the form of calcium oxide has long been used in acidic water pH regulator applied. It was burnt limestone with a high lime content. Examples of this type of lime are products from Orsa and Calcium in Malmö (Sweden), The invention relates to an agent that has a satisfactory micro and Macro flake formation in such a way that the build-up of the flakes in the downstream Devices significant technical effects in the obtained sludge with it. The sludge quality gives, for example, improvements in terms of the amount of sludge, the possibility of sludge dewatering, the sedimentation rate, increasing effects for the precipitation of heavy metals UoSoWo The precipitant according to the invention is essentially by a certain composition of the Chemical elements contained in the mean, as from analytical data according to claim 1 emerges.

Table 1 Chemical composition of common lime and precipitants according to the invention.

Chemical high percentage precipitation precipitation analysis lime medium 1 according to medium 2 according to the invention of the invention 5102 5.5 19.5 30.4 A1203 0.4 7.3 10.9 Fe203 0.2 4.7 8.1 CaO 91.5 61.9 44.1 MgO 1.3 1.8 2.1 Alkaline, S-compounds, Annealed etc .; up to 100% Table II Example of compositions of precipitation agents according to the invention.

Mineral designation 1 2 3 4 5 Calcium silicate CS 10 - - - -Calcium silicate -C2S 29 30 54 49 40 calcium aluminate CA - 6 9 7 7 magnesium aluminum silicate M2AS 18 - - - -Calcium aluminum silicate C2AS - 10 5 - -Calcium aluminate ferrite C4AF 14 7 17 14 12 Calcium Oxide C 5 14 3 21 34 Calcium Ferrite CF 6 4 4 - -Magnesium Silicate MS 10 5 - 4 2 aluminum silicate AS - 3 "-, - iron silicate FS - 4 - - -quartz S 5 12 2 - -Oxvde Si ° 2 32 30.4 22 19.5 15 A1203 13 10.9 11 7.3 7 Fe203 9 8.1 9 4.7 4 CaO 32 44.1 52 61.9 68 MgO 10 2.1 0.2 1.8 1 96 95.6 94 95.2 95 basic basic oxides Acid Oxide Molar Ratio 1.1 1.3 1.8 2.7 3.7 The precipitant 2 in the above Table corresponds to the precipitating agent 2 in Table I, and the precipitating agent 4 corresponds to precipitant 1 in Table 1.

It is important for the invention that the ratio is basic oxides to acidic oxides the precipitant is properly matched. The molar ratio basic oxides / acidic oxides must not be lower than 1, so that a satisfactory one Cleaning level should be achieved. When the molar ratio exceeds 5, the good properties of the obtained sludge gradually decrease.

When the product has been fired satisfactorily, the molar ratio means 1.0 - 5.0 that sufficient amounts of mineral to ensure the technical effects, which will be set out later have been obtained.

Active mineral in the high percentage lime commonly used is essentially calcium oxide while in the precipitating agents according to the invention the active minerals in the calcium silicate, calcium ferrite, calcium aluminate groups, Calcium aluminum silicate, calcium aluminate ferrite, calcium iron silicate, calcium magnesium aluminate ferrite, Aluminum silicate, iron silicate, iron aluminum oxide, lime oxide, magnesium silicate and Quartz can be found.

In the attached diagrams are some examples of using the invention technical effects achieved. Diagram 1 shows that a lower Sludge volume has been obtained, diagram 2 shows that only a small amount suspended matter remained after the post-precipitation, Diagrams 3 uru 4 show the result of precipitation of nutrient salts and diagram 5 is a X-ray diffractogram indicating the composition of the precipitant 2. This diagram shows the main X-ray reflections for various Minerals found in the precipitating agent were preserved.

In the case of biologically treated wastewater, certain substances remain suspended6 return. In the case of post-precipitation with normal lime, 80% of the substances remain in suspension back, while with the precipitation agent according to the invention only 20% after the post-precipitation back to lb # in # Diagram 2 shows this effect. This circumstance indicates that flakes formed with the precipitating agent according to the invention are significantly better Sedimentation capacity and increased drainage capacity in the downstream Own process plant. This means a technical one that cannot be overlooked at the moment Improvement in both drinking water and wastewater treatment technology.

There are several methods used in wastewater purification. The most common is the direct> 1 precipitation method (the precipitating agent is used before the biological Stage added) and the post-precipitation method (so-called third stage; the precipitating agent is added after the biological stage). The agent according to the invention results Nutrient salt precipitation results that meet the required guide values for wastewater treatment plants correspond. This can be seen in diagrams 3 and 4. Diagram 3 concerns directly precipitated wastewater, i.e. water not previously biologically treated The initial phosphorus content was 18 mg P / l. As can be seen, the two means according to the invention can Reach the limit of 1 mg P / l. Diagram 4 relates to wastewater that has been precipitated, after it has only been biologically cleaned. The initial phosphorous content was in this case 5.6 mg P / 1 means 1 and 2 according to the invention and common lime in this case use the same amount, namely S00gper 1, around the guideline value 1 mg P / 1 in the exiting water. Post-precipitation - the third stage - is currently recommended by the Swedish Nature Conservation Agency.

One possible explanation for the improved achieved according to the invention The effect is that the precipitating agent according to the invention is contrary to the ordinary applied chemically pure aluminum sulfate and / or high quality lime oxide minerals of the type indicated above. These minerals are different from one another Solubility products. This causes the formed flakes of aluminum and Iron cores made from less soluble minerals, calcium phosphates and / or complexes Contains various kinds of salts such as mineral hydrates and heavy metals. This causes, that the flakes are heavier, denser and possibly more prone to adsorption for other insoluble salts and substances suspended from the biological stage. As a result, the formed flakes have improved sedimentation effects and. Drainage effects.

The process for the preparation of the precipitating agent according to the invention is illuminated in the exemplary embodiments given below.

Example 1 Low-percentage limestone, crushed and to a maximum Milled 20 ffi larger than 90 », was mixed with quartzite, which was reduced to a maximum of 5% larger than 90 # Q was ground, in the proportions 82:18. The mixture was processed into granules and introduced into a 90 m long rotary kiln and placed in slightly oxidizing atmosphere with a temperature in the combustion zone of 1000-1050 ° C burned. The total residence time of the material in the furnace was approx. 5 hours and the temperature level between 90,000 and 105,000 was between 2 and 3 hours. Of the Fired and cooled clinker became a fineness of 10-20% greater than 60 ## and and ground 0-2% larger than 90gb.

The analysis of the starting material and the final product will be shown in the following compilation.

Analysis: Limestone Quartzite Product SiO2 12.9% 70 ffi 34.2% A1203 4.8 ~ 4.0 ~ # 5.9 ~ Fe 2 O 3 3.1 ~ 0.5 ~ 3.9 CaO 40.9 "1.0" 41.7 # 1 MgO 1.2 "0.5 "1.6 Loss on ignition 34.0" 25 "0 Molar ratio of basic oxides = 1.21 acidic oxides example 2 Schifferstein was ground until more than 80% passed through a 90 A sieve could and was mixed with gravel burnout in the proportions 95: 5. The gravel burn contained a maximum of 5% greater than 90 ç. After the production of granules, the The mixture is introduced into a 90 m long rotary kiln and heated at a temperature of approx. Burned 105000. The total dwell time in the oven was approx. 5 hours and the temperature level 900 ° C-1050 ° C was between 2 and 3 hours. The fired and chilled product was ground to the same fineness as in Example 1.

The composition of the raw material and the final product will be shown in the following compilation.

Analysis: Schifferstein gravel burn-off product SiO2 22.1% 5.0% 24.6 % Al2O3 7.9% 8.0% 11.0% Fe2O3 2.0 "82.0" ~ 8.4 "CaO 40.0" 1.0 "53.1" MgO 0.1 "0.1" 0.1 "Loss on ignition 30.0" 0 1 # 0 # 1 molar ratio of basic oxides = 1.45 acidic oxides Example 3 High-percentage limestone, ground to a fineness of a maximum of 20% larger than 90 #, was with gravel burn, a maximum of 5% larger than 90 or, mixed in proportions 90110. After mixing and forming granules, the Material is fed into a 90 m long rotary kiln, where the material is kept at a temperature from oa. 125,000 was burned in a weakly oxidizing atmosphere. The dwell time in the oven lasted approx. 7 hours and the zuTemp eratur et temperature increase of 90,000 to 125000 takes about 4 hours. The product was ground to the same fineness as indicated in example 1 and 2.

The composition of the raw material and the final product are given below Analysis: Limestone Gravel Burn Product Si02 8.0% 5.0% 11.5% A1203 2.7 ~ 8.0 " 3.8 Fe2 ° 3 1.6 "82.0" 14.3 CaO 49.0 "1.0" 65.8 MgO 2.0 "0.1" 2.7 Loss on ignition 37.0 "0 o 0 molar ratio of basic oxides to acidic oxides = 4.1 in general the temperature during firing between 900 and 150,000, preferably between 950 and 130,000.

- patent claims -

Claims (1)

Claims 1. Precipitants for purifying water by Sedimentation, d u r c h e k e n n z e i c h n e vt that it consists of a mixture consists of minerals, of which at least after a previous firing The main part is completely or partially water-soluble and the mixture has a molar ratio between basic and acidic oxides from 1.0 to 5.0 and the following chemical Analysis data of the annealed sample results in: SiO2 15 - 40% A120 5 - 15% Fe203 3 - 12% CaO 15-70% MgO 0.1-20% 2. Precipitant according to Claim 1, d a d u r c h g it is not stated that it consists of minerals of the mineral groups calcium silicates, Calcium ferrites, calcium aluminates, calcium aluminum silicates, calcium aluminate ferrites Calcium oxide, calcium iron silicates, calcium magnesium aluminate ferrites # aluminum silicates, Iron silicates, quartz, magnesium silicates, and iron aluminum oxide. 3. A method for producing a precipitating agent according to claim 1 for the purification of water through sedimentation c h n e t that starting materials are mixed and used in such a ratio at such a temperature, preferably a temperature between 900 and 1.5000C that the fired mixture is completely or partially water-soluble Contains minerals and a molar ratio between basic and acidic oxides of 1.0 - 5.0 as well as the following chemical analysis data of the annealed sample: SiO2 15 - 40% A12O3 5 - 15% Fe203 3 - 12% CaO 15 - 70% MgO o, i - .20% L. e e page