JP6366186B2 - Mercury recovery device and mercury recovery method - Google Patents

Description

  The present invention relates to an apparatus and method for recovering mercury from a substance containing mercury such as dust and coal ash recovered from cement kiln exhaust gas.

  Cement kiln exhaust gas contains mercury contained in natural raw materials such as limestone, which is the main raw material of cement, and trace amounts of mercury derived from mercury contained in recycled resources such as fly ash. If the mercury in the cement kiln exhaust gas increases, it may cause air pollution, which may hinder the expansion of the use of recycled resources such as fly ash.

  Therefore, in Patent Document 1, as shown in FIG. 2, a hot air furnace 12 for heating air A11 and a kiln dust D11 containing mercury recovered from cement kiln exhaust gas and directly heated with gas G11 from the hot air furnace 12 are extracted. Duct 13, cyclone 14 that collects carrier gas G 12 containing volatile mercury and separates it into mercury-containing gas G 13 and mercury removal dust D 12, and mercury-containing gas G 13 that collects mercury-containing gas G 14 and removes mercury Bag filter 15 separated into dust D13, heat exchanger 16 for recovering heat from mercury-containing gas G14, activated carbon adsorption tower 19 for recovering mercury contained in mercury-containing gas G15, and heat generated in heat exchanger 16 A cement kiln exhaust gas treatment device 11 including a fan 18 for supplying the hot air furnace 12 to the hot air furnace 12 has been proposed.

JP 2011-88770 A

  However, in the processing method described in Patent Document 1, it is not easy to uniformly heat the kiln dust D11, and in order to volatilize the mercury in the kiln dust D11 without leakage, a large amount of gas G11 used for heating must be used. I didn't get it. For this reason, the amount of the transfer gas G12 increases, and the related equipment such as the extraction duct 13 as the heating device, the cyclone 14 and the bag filter 15 as the dust collector, and the activated carbon adsorption tower 19 as the mercury adsorption device are enlarged. Inevitably, there was a problem that the equipment cost and the operating cost were increased.

  Therefore, the present invention has been made in view of the above problems in the prior art, and an object of the present invention is to efficiently recover mercury from a substance containing mercury at a low cost.

  In order to achieve the above object, the present invention is a mercury recovery apparatus, which indirectly heats a substance containing mercury, volatilizes mercury contained in the substance, and discharges a carrier gas containing volatile mercury. A dust collector that collects the carrier gas discharged from the indirect heating device, a dilution gas addition device that adds a dilution gas to the exhaust gas of the dust collector, and the diluted exhaust gas. And a mercury adsorption device that adsorbs and collects mercury.

  According to the present invention, since a substance containing mercury can be uniformly heated without using a large amount of gas by using an indirect heating device, the amount of transport gas discharged from the indirect heating device can be reduced. It is possible to reduce the size of related equipment such as an indirect heating device, a dust collector, and a mercury adsorption device. Further, contact between the substance containing mercury and the heating medium can prevent mercury from being contained in the heating medium, and the heating medium processing apparatus can be simplified.

  Furthermore, by adding a dilution gas to the exhaust gas of the dust collector, the mercury adsorption efficiency can be improved, and the size of the dust collector can be reduced by not increasing the amount of transport gas introduced into the dust collector. Can be maintained.

  In the mercury recovery apparatus, the indirect heating device includes a gas discharge unit that discharges the transfer gas containing the volatile mercury, and a substance discharge unit that discharges a mercury removal material generated by removing mercury from the mercury-containing substance. Can be provided. Thereby, since only the volatile mercury has to be transported without transporting the mercury removing substance by the transport gas, the transport gas can be further reduced. Further, the indirect heating device can be an external heat kiln.

  Furthermore, the present invention is a method for recovering mercury, which indirectly heats a substance containing mercury to volatilize mercury contained in the substance, collects a carrier gas containing volatile mercury, and exhausts the exhaust gas after the dust collection. A gas for dilution is added to mercury, and mercury contained in the diluted exhaust gas is adsorbed and recovered.

  According to the present invention, as in the case of the above-mentioned invention, since the substance containing mercury can be heated uniformly by performing indirect heating without using a large amount of gas, the amount of gas for transportation can be reduced. The cost required for indirect heating, dust collection, and mercury adsorption can be reduced. Further, contact of the substance containing mercury with the heating medium can prevent the heating medium from containing mercury, and the heating medium can be easily processed.

  Furthermore, by adding a dilution gas to the exhaust gas after dust collection, the mercury adsorption efficiency can be improved, and the cost required for dust collection can be kept low by not increasing the amount of transport gas to be collected. Can do.

In the mercury recovery method, the gas containing volatile mercury generated by the indirect heating and the mercury removing material generated by removing mercury from the mercury-containing substance are separated from each other, and the gas containing volatile mercury is transferred to the mercury Gas can be used. Thereby, since only the volatile mercury has to be transported without transporting the mercury removing substance by the transport gas, the transport gas can be further reduced.

Moreover, mercury adsorption efficiency can be further improved by adding a dilution gas to the exhaust gas after dust collection so that the mercury concentration of the exhaust gas is 1,000 mg / m ³ or less. Further, the mercury-containing substance can be dust or coal ash recovered from cement kiln exhaust gas. The temperature of the dilution gas can be set to 20 ° C. or more and 80 ° C. or less, the exhaust gas after dust collection can be cooled and diluted, and mercury can be efficiently adsorbed and recovered.

  As described above, according to the present invention, mercury can be efficiently recovered from a substance containing mercury at low cost.

It is a whole lineblock diagram showing one embodiment of a mercury recovery device concerning the present invention. It is a whole block diagram which shows an example of the conventional mercury collection | recovery apparatus.

  Next, an embodiment for carrying out the present invention will be described in detail with reference to the drawings. In the following, a case where dust collected from cement kiln exhaust gas is treated by the mercury recovery apparatus according to the present invention will be described as an example.

  FIG. 1 shows an embodiment of a mercury recovery apparatus according to the present invention. This mercury recovery apparatus 1 is supplied from a hopper 2 that stores kiln dust D1 containing mercury recovered from a cement kiln exhaust gas, and a hopper 2. The screw conveyor 3 that conveys the mercury-containing dust D3 in which the kiln dust D1 and the mercury removal dust D2 to be described later are mixed, and the mercury-containing dust D3 supplied from the screw conveyor 3 is indirectly heated and contains the volatilized mercury by the indirect heating. An external heat kiln 4 that separates the gas and the mercury removal dust D4 from each other; a bag filter 5 that separates the carrier gas G1 discharged from the external heat kiln 4 into the mercury-containing gas G2 and the mercury removal dust D2; A fan 6 for adding a dilution air A2 to the mercury-containing gas G2 discharged from 5 to form a mercury dilution gas G3, and mercury dilution By adsorbing the mercury contained in the scan G3 and a activated carbon adsorption tower 7 to recover.

  The external heat kiln 4 as an indirect heating device includes a rotary kiln 4a, a jacket 4b that surrounds the kiln 4a and into which high-temperature gas is introduced, a dust supply unit 4c that supplies mercury-containing dust D3, and air A1. It has a gas introduction part 4d to be introduced, a gas discharge part 4e for discharging the carrier gas G1, and a dust discharge part 4f for discharging the mercury removal dust D4.

  As the bag filter 5 as a dust collector, a high heat-resistant bag filter having heat resistance up to about 900 ° C. or a normal heat filter can be used.

  An activated carbon adsorption tower 7 as a mercury adsorption device is provided for adsorbing and recovering mercury in the mercury dilution gas G3. As the activated carbon used in the activated carbon adsorption tower 7, it is desirable to select an activated carbon that is particularly excellent in mercury recovery ability from among commercially available activated carbons. Specifically, a sulfur impregnation treatment adjusted for mercury adsorption is performed. Activated carbon is preferred.

  Next, the operation of the mercury recovery apparatus 1 having the above configuration will be described with reference to FIG.

  Hot gas is introduced into the jacket 4b of the external heat kiln 4 to heat the inside of the kiln 4a, and the kiln dust D1 is supplied to the kiln 4a via the screw conveyor 3 and indirectly heated. The kiln dust D1 is heated in contact with the inner surface of the kiln 4a having a high temperature, and mercury is volatilized. On the other hand, the mercury-removed dust D4 from which mercury has been removed is discharged out of the system from the dust discharge part 4f and used as a cement raw material or the like.

  Mercury volatilized by the air A1 introduced from the gas introduction part 4d is transported, and a transport gas G1 containing volatile mercury is discharged from the gas discharge part 4e. The carrier gas G1 is introduced into the bag filter 5 and separated into the mercury-containing gas G2 and the mercury removing dust D2.

Dilution air A2 is added to the mercury-containing gas G2 from the fan 6 so that the mercury concentration of the mercury-containing gas G2 becomes a concentration suitable for adsorption in the activated carbon adsorption tower 7 (1,000 mg / m ³ or less). After that, mercury in the mercury dilution gas G3 is adsorbed by the activated carbon adsorption tower 7 and recovered. Here, by setting the temperature of the dilution air A2 to 20 ° C. to 80 ° C., the mercury-containing gas G2 can be cooled as well as being diluted, and the adsorption efficiency in the activated carbon adsorption tower 7 can be increased. The mercury removal gas G4 discharged from the activated carbon adsorption tower 7 is discharged into the atmosphere after appropriate exhaust gas treatment. On the other hand, the mercury removal dust D2 is returned to the screw conveyor 3 and supplied to the kiln 4a as the mercury-containing dust D3 together with the kiln dust D1.

  As described above, in the above-described embodiment, since the mercury-containing dust D3 can be uniformly heated by the jacket 4b without using a large amount of gas by using the external heat kiln 4, the gas of the external heat kiln 4 is used. The amount of the transfer gas G1 discharged from the discharge unit 4e can be reduced, and the related equipment such as the external heat kiln 4, the bag filter 5, and the activated carbon adsorption tower 7 can be downsized. Further, it is possible to prevent mercury from being contained in the heating medium due to the contact between the mercury-containing dust D3 and the heating medium (in this embodiment, the high temperature gas introduced into the jacket 4b), and the heating medium processing apparatus can be simplified. Can be.

  Further, by adding dilution air A2 to the mercury-containing gas G2 discharged from the bag filter 5, the mercury adsorption efficiency in the activated carbon adsorption tower 7 is improved and the amount of the carrier gas G1 introduced into the bag filter 5 is reduced. Since it is not necessary to increase the size, the downsizing of the bag filter 5 can be maintained.

  In addition, although the said embodiment demonstrated the case where the dust collect | recovered from cement kiln exhaust gas was processed, if it is a substance containing mercury, such as coal ash, another substance can also be processed.

  Moreover, it can replace with the air A1 introduce | transduced into the gas introduction part 4d of the external heat kiln 4, can also use an inert gas, and can also use an inert gas other than the dilution air A2 as a dilution gas. Moreover, the heated air A1 can also be introduce | transduced into the gas introduction part 4d of the external heat kiln 4, and the air A1 can also be retained in the kiln 4a and can be heated. In heating the inside of the kiln 4a of the external heat kiln 4, a heating medium other than the high-temperature gas may be used.

  Furthermore, instead of the external heat kiln 4, the bag filter 5, and the activated carbon adsorption tower 7 in the mercury recovery apparatus 1, other types of indirect heating devices, dust collectors, and mercury adsorption devices can be used. The external heat kiln 4 has a gas discharge part 4e for discharging the transfer gas G1 and a dust discharge part 4f for discharging the mercury removal dust D4, and discharges the transfer gas G1 and the mercury removal dust D4 separately. The bag filter 5 is provided because a part of the mercury removing dust is mixed in the carrier gas G1. Even if the concentration of mercury removal dust in the carrier gas increases, the mercury collector dust is collected by the dust collector using an indirect heating device that has a common discharge section for the carrier gas and mercury removal dust. Can respond.

DESCRIPTION OF SYMBOLS 1 Mercury recovery apparatus 2 Hopper 3 Screw conveyor 4 External heat kiln 4a Kiln 4b Jacket 4c Dust supply part 4d Gas introduction part 4e Gas discharge part 4f Dust discharge part 5 Bag filter 6 Fan 7 Activated carbon adsorption tower A1 Air A2 Dilution air D1 Kiln dust D2 Mercury removal dust D3 Mercury-containing dust D4 Mercury removal dust G1 Transport gas G2 Mercury-containing gas G3 Mercury dilution gas G4 Mercury removal gas

Claims (8)

An indirect heating device that indirectly heats a substance containing mercury to volatilize mercury contained in the substance, and discharges a carrier gas containing volatile mercury;
A dust collector that collects the carrier gas discharged from the indirect heating device;
A dilution gas addition device for adding a dilution gas to the exhaust gas of the dust collector;
A mercury recovery apparatus comprising: a mercury adsorption device that adsorbs and collects mercury contained in the diluted exhaust gas.   The indirect heating device includes a gas discharge unit that discharges the carrier gas containing the volatile mercury, and a substance discharge unit that discharges a mercury removing substance generated by removing mercury from the mercury-containing substance. The mercury recovery apparatus according to claim 1.   The mercury recovery apparatus according to claim 1, wherein the indirect heating device is an external heat kiln. Indirectly heating a substance containing mercury to volatilize mercury contained in the substance,
Collecting transport gas containing volatile mercury,
Add dilution gas to the exhaust gas after dust collection,
A mercury recovery method comprising adsorbing and recovering mercury contained in the diluted exhaust gas. Separating the gas containing volatile mercury generated by the indirect heating and the mercury removing material generated by removing mercury from the substance containing mercury, and using the gas containing volatile mercury as the carrier gas. The mercury recovery method according to claim 4, wherein The mercury recovery method according to claim 4 or 5, wherein a dilution gas is added to the exhaust gas after dust collection so that the mercury concentration of the exhaust gas is 1,000 mg / m ³ or less.   The mercury recovery method according to claim 4, 5 or 6, wherein the substance containing mercury is dust or coal ash recovered from a cement kiln exhaust gas.   The mercury recovery method according to claim 4, wherein the temperature of the dilution gas is 20 ° C. or higher and 80 ° C. or lower.