RU2036843C1 - Method of removing oil contaminants from water - Google Patents

Abstract

FIELD: removal of petroleum and petroleum products from water surface and from sewage water. SUBSTANCE: method involves sorbing above-mentioned products by hull of rice grains carbonized at 450-600 C and atmospheric pressure or at 500-700 C and pressure of 200-759 mm of mercury column or in nitrogen medium at 550-650 C and atmospheric pressure. Recovery of sorbent is effectuated by hydrocarbon solvent (benzine, rekosine), organic solvent (methylated spirit) or their mixture. EFFECT: increased efficiency in removal of contaminants. 2 cl

Description

 The invention relates to methods for removing oil and oil products from the water surface and from wastewater by adsorption with carbon-containing sorbents and can be used in the field of environmental protection in various sectors of the economy.

 A known method of removing oils from water using carbonized walnut shells as a sorbent with its subsequent liquid regeneration.

 The main disadvantage of this method is the insufficiently high degree of removal of oil and oil products from water, which reduces the efficiency of the process as a whole.

 The aim of the invention is to increase the efficiency of the process of removing oil and oil products from the surface of the water and from wastewater.

According to the invention, the goal is achieved by a method of removing oil and oil products from the surface of the water and from wastewater by adsorbing sorbents from the husk (shell) of rice grain subjected to heat treatment, followed by regeneration of the sorbent. The heat treatment of rice grain husks at atmospheric pressure in air is performed at 450-600 ° ^C. The heat treatment of rice grain husks at atmospheric pressure under a nitrogen atmosphere is carried out at 550-650 ° ^C. The heat treatment of rice grain husks at a residual pressure of 200-759 mm Hg in the air is carried out at 500-700 ^about C.

Treatment of water or wastewater surface offered sorbent is carried out at 0-100 ^C. The regeneration of used sorbent is carried out by treatment with hydrocarbon solvents (gasoline, kerosene, etc.) or organic solvents (alcohols, etc.) or their mixtures. In this case, an effective at least seven-fold reuse of the sorbent is possible. Disposal of the spent sorbent is carried out by burning it to obtain an ash-like product containing trace elements, and used as fertilizer.

EXAMPLE EXAMPLE 1. 100 g of the husks of rice grains were charged in a crucible muffle furnace and subjected to heat treatment at atmospheric pressure in air at 450-600 ^C for 15 min. As a result of heat treatment, an sorbent of husk of black rice grains is obtained in an average amount of 36.0 g.

EXAMPLE EXAMPLE 2 100 g of the husks of rice grains were charged in a crucible muffle furnace and subjected to heat treatment at atmospheric pressure under nitrogen at 550-650 ^C for 15 min. As a result of heat treatment, an sorbent husk of black rice grains is obtained in an average amount of 46.0 g.

PRI me R 3. 100 g of husk of rice grains are loaded into a crucible of a muffle furnace and subjected to heat treatment at a residual pressure of 200-759 mm Hg in air at 500-700 ^C for 15 min. As a result of heat treatment, a sorbent husk of black rice grains is obtained in an average amount of 62.0 g.

 PRI me R 4. 50.0 g of Romashkinskaya oil is poured onto the surface of the water in a glass beaker with a diameter of 300 mm to obtain a blurred oil stain. Then, 7.5 g of the sorbent obtained according to Example 1 is applied to the washed-out oil slick. The oil slick is sorbed by the sorbent for no more than 10 minutes and disappears completely. The sorbent, saturated with oil, does not sink and is easily collected mechanically from the surface of the water and undergoes regeneration.

 The regeneration of oil-saturated sorbent is carried out as follows. The sorbent is placed in a separatory funnel and treated with 125 ml of gasoline. In this case, the sorbent is completely "washed" from oil. The resulting solution of oil in gasoline from a separatory funnel is loaded into a distillation flask with a Widmar nozzle. As a result of distillation of this solution, 125 ml of distillate (gasoline) and the remainder of the oil (in the amount of 49.95 g) are obtained.

For comparison, 7.5 g of a black walnut shell is applied to a blurred oil slick obtained under similar conditions as above. Black walnut shells obtained by heat treatment of 100 g of walnut shell crucible in a muffle furnace at atmospheric pressure in air at 450-600 ^C for 15 min. The yield of black walnut shells is on average 10 g.

 An oil slick is sorbed by this sorbent for 10 minutes and does not completely disappear. Oil sorbent is collected mechanically from the surface of the water. The regeneration of oil-saturated sorbent is carried out under the same conditions described above. The distillation of a solution of oil in gasoline gives 125 ml of distillate (gasoline) and the remainder of the oil (in the amount of 22.5 g).

 PRI me R 5. 50.0 g of chamomile oil is poured onto the surface of the water in a glass beaker with a diameter of 300 ml to obtain a blurred oil stain. Then, 6.8 g of the sorbent obtained according to Example 2 is applied to the washed-out oil slick. The oil slick is sorbed by the sorbent for no more than 10 minutes and disappears completely. The sorbent, saturated with oil, does not sink and is easily collected mechanically from the surface of the water and undergoes regeneration.

 The regeneration of oil-saturated sorbent is carried out analogously to example 4. The result is 125 ml of gasoline and 49.95 g of oil.

For comparison, 6.8 g of black walnut shells are applied to a blurred oil stain obtained under the similar conditions above. Black walnut shells obtained by heat treatment of 100 g of walnut shell crucible in a muffle furnace at atmospheric pressure under nitrogen at 550-650 ^C for 15 min. The yield of black walnut shells averages 17 g.

 An oil slick is sorbed by this sorbent for 10 minutes and does not completely disappear. Oil sorbent is collected mechanically from the surface of the water. The regeneration of oil-saturated sorbent is carried out under the above conditions. The result is 125 ml of gasoline and 22.7 g of oil.

 PRI me R 6. 50.0 g of oil is poured onto the surface of the water in a glass beaker with a diameter of 300 ml to obtain a blurred oil stain. Then, 6.5 g of the sorbent obtained according to Example 3 is applied to the washed-out oil slick. The oil slick is sorbed by the sorbent for no more than 10 minutes and disappears completely. The sorbent, saturated with oil, does not sink and is easily collected mechanically from the surface of the water and undergoes regeneration.

 The regeneration of oil-saturated sorbent is carried out analogously to example 4. The result is 125 ml of gasoline and 49.95 g of oil.

For comparison, 6.5 g of a granulated black walnut shell is applied to a blurred oil slick obtained under similar conditions above. Black walnut shells obtained by heat treatment (e.g., 100 g of walnut shell crucible in a muffle furnace at a residual pressure of 200-759 mm Hg) in air at 500-700 ^C for 15 min. The yield of black walnut shells is on average 21 g.

 An oil slick is sorbed by this sorbent for 10 minutes and does not completely disappear. Oil sorbent is collected mechanically from the surface of the water. The regeneration of oil-saturated sorbent is carried out under the same conditions described above. The result is 125 ml of gasoline and 22.9 g of oil.

PRI me R 7. Pour on the surface of industrial wastewater in a treatment tank (surface area 4 m ² ), 450 g of Mordovian-Karmal natural bitumen extracted from bituminous rock by in situ combustion, with the formation of a blurred bitumen stain. Then, 70 g of the sorbent obtained according to Example 1 is applied to the blurred bitumen stain. The bitumen stain is sorbed for 10 min and completely disappears. The sorbent saturated with natural bitumen does not sink and is easily collected by a scraper or mesh trap from the surface of the water and undergoes regeneration.

 The regeneration of a sorbent saturated with natural bitumen is carried out as follows.

 The sorbent is placed in a separatory funnel and treated with 1000 ml of an alcohol-gasoline mixture (20% ethanol + 80% gasoline). In this case, the sorbent is completely "washed" from natural bitumen. The resulting solution from the separatory funnel is loaded into a distillation cube apparatus ARN-2. As a result of distillation of the solution, a distillate gives an alcohol-gasoline mixture (in the amount of 990 ml) and the residue is natural bitumen (in the amount of 443 g).

 PRI me R 8. In a glass adsorption column, the sorbent obtained in example 1 is loaded in an amount of 0.15 g. 2000 ml of waste water containing 200 mg of Romashkin oil was passed through an adsorption column with a sorbent. As a result, water with an oil content of not more than 0.3 mg / L is obtained at the column outlet.

 The regeneration of oil-saturated sorbent is carried out as follows.

 10 ml of gasoline is passed through an adsorption column with an oil-saturated sorbent. In this case, the sorbent is completely "washed" from oil. The resulting solution of oil in gasoline is loaded into a distillation flask with a Widmar nozzle. As a result of distillation of this solution, 10 ml of gasoline distillate and the remainder of the oil (in the amount of 199.5 mg) are obtained.

 For comparison, under the above conditions, waste water is passed through 0.15 g of black walnut shell obtained as in Example 4. As a result, water with a content of 1.9 mg / l of oil is obtained at the column outlet.

 The regeneration of oil-saturated sorbent is carried out under the above conditions. The distillation of a solution of oil in gasoline gives 10 ml of gasoline distillate and the remainder of the oil (in the amount of 196.2 mg).

 PRI me R 9. In a glass adsorption column load the sorbent obtained in example 3, in the amount of 0.15 g. Through an adsorption column with a sorbent 2000 ml of wastewater containing 100 mg of industrial oil is passed. As a result, water is obtained at the column outlet with an industrial oil content of not more than 0.3 mg / l.

 The regeneration of a sorbent saturated with industrial oil is carried out as follows. 10 ml of gasoline is passed through an adsorption column with a saturated industrial oil sorbent. In this case, the sorbent is completely "washed" from industrial oil. The resulting solution of industrial oil in gasoline was charged into a distillation flask with a Widmar nozzle. As a result of distillation of this solution, 9.8 ml of gasoline distillate and the remainder of industrial oil (in the amount of 99.5 mg) are obtained.

 For comparison, under the above conditions, waste water is passed through 0.15 g of black walnut shell obtained as in Example 6. As a result, water with an industrial oil content of 1.5 mg / L is obtained at the column outlet.

 The regeneration of a sorbent saturated with industrial oil is carried out under the above conditions. As a result of distillation of a solution of industrial oil in gasoline, 9.8 ml of gasoline distillate and the remainder of the industrial oil (in the amount of 97.0 mg) are obtained.

 From the data of the above examples it can be seen that the invention in comparison with the known method can improve the degree of purification of water. The indicated advantage of the proposed method, as well as the availability and low cost of the sorbent used in it during its industrial use, can significantly increase the efficiency of the process.

Claims (2)

1. METHOD FOR REMOVING OIL POLLUTIONS FROM WATER, including contacting water with a sorbent based on carbonized shells of plant fruits and regenerating the sorbent with liquid, characterized in that rice husk carbonized in air at 450 to 600 ^° C and atmospheric pressure is used as the sorbent. , or at a temperature of 500,700 ^o C and a pressure of 200,759 mm Hg. or in a nitrogen atmosphere at a temperature of 550,650 ^{° C.} and atmospheric pressure, and as a liquid, a hydrocarbon or organic solvent or a mixture thereof.  2. The method according to claim 1, characterized in that gasoline or kerosene is used as the hydrocarbon solvent, and alcohol as the organic solvent.