KR102215311B1 - iron-kylate wet desulfurizer for removing high-concentration hydrogen sulfide - Google Patents

Abstract

The present invention relates to an iron-chelate wet desulfurizer for removing high-concentration hydrogen sulfide to reduce operation costs. According to the present invention, odor gas containing high-concentration hydrogen sulfide generated from a digestion tank is supplied to a reaction tower by a rising ascending air current, an aqueous iron-chelate solution, which is a chemical solution, is supplied to the reaction tower through a nozzle by descending air current, a reaction solution containing sulfur captured in the aqueous iron-chelate solution is free dropped and supplied to a precipitation tank, a sulfur compound precipitated in the precipitation tank and a sulfur compound, which is a scum layer floating on a liquid surface, are transferred to a dehydrator so that the recycled aqueous iron-chelate solution is supplied to upstream of a recycling tank after the sulfur compounds are removed by the dehydrator, and lower liquid in the precipitation tank is discharged to upstream of the recycling tank, and the aqueous iron-chelate solution, which is supplied to upstream of the recycling tank after the sulfur compounds are removed in the precipitation tank, is aerated while discharged in a zigzag manner to be discharged in a chemical solution storage tank disposed on the lower part of the reaction tower.

Description

Iron-kylate wet desulfurizer for removing high-concentration hydrogen sulfide

The present invention relates to an iron chelate wet desulfurizer for removing high concentration hydrogen sulfide, and more particularly, to a wet desulfurizer for removing hydrogen sulfide generated in a digester with iron chelate as a chemical solution.

In general, gases generated from hateful facilities, etc. generate odors.

As a method of removing the odor gas, there is a method of installing a plurality of nozzles in a deodorizing device and spraying a chemical liquid on the gas containing the odor introduced into the deodorization tank at a deodorizing facility (chemical liquid method). A method in which a layer of an adsorbent such as activated carbon, silica gel, and zeolite is disposed in the tank to adsorb odor substances (activated carbon adsorption method) or a method in which a specific microbial layer is disposed instead of the adsorbent so that the microorganisms decompose odor-generating substances (microbial contact Method), etc.

Among these methods, a device for removing odor by a chemical solution is disclosed in Patent Nos. 1534602, 1912305, and 2129824, which have been patent applications and registered by the present applicant.

The above-described odor removal apparatus is adapted to neutralize by supplying an acidic chemical solution to an alkali component among odor components, and to supply an alkali component to the acid component for neutralization.

However, the odor removal device that neutralizes alkali and acid components is inefficient when applied to odor gases containing a large amount of hydrogen sulfide, such as a sewage treatment plant, and in particular, generates salts during the neutralization process and supplies chemicals to odor gases. The nozzle is clogged, causing a problem of having to periodically clean the nozzle.

The present invention has a problem in solving the above problems.

In the present invention, an odor gas containing a high concentration of hydrogen sulfide generated in a digester is supplied to the reaction tower as an upward airflow, and an aqueous iron chelate solution, which is a chemical solution, is supplied to the reaction tower through a nozzle in a downward flow, and to the iron chelate aqueous solution. The reaction solution containing the collected sulfur is supplied naturally to the settling tank, and the sulfur compounds precipitated in the settling tank and the sulfur compounds, which are scum layers floating on the liquid level, are transferred to a dehydrator and removed by a dehydrator, and then supplied to the upstream side of the regeneration tank. The lower liquid in the sedimentation tank is also discharged to the upstream side of the regeneration tank, and the iron chelate regeneration liquid supplied to the upstream side of the regeneration tank by filtering sulfur compounds in the sedimentation tank is discharged in a zigzag manner, and aeration treatment is carried out to place it under the reaction tower. The above problems can be solved by being discharged to the chemical storage tank.

The present invention is applied to a malodorous gas containing a large amount of hydrogen sulfide, such as a digester, by means of the above-described problem solving means, it is possible to efficiently remove hydrogen sulfide from the odorous gas intensively, and further, the neutralization process is eliminated. It prevents clogging of the nozzle supplying the chemical solution to the odorous gas and eliminates periodic cleaning of the nozzle, significantly reducing maintenance costs, as well as reusing and reusing the iron chelate aqueous solution, a chemical solution. Operation cost can be reduced.

1 is a front view showing the'iron chelate wet desulfurizer for removing high concentration hydrogen sulfide' of an embodiment according to the present invention;
Figure 2 is a side view of Figure 1,
3 is a plan view showing a settling tank, a regeneration tank, and a chemical solution storage tank of FIG. 1, and
Figure 4 is a detailed view showing the variable buoyancy type bulkhead means of Figure 1;

Hereinafter, the'iron chelate wet desulfurizer for removing high concentration hydrogen sulfide' of an embodiment according to the present invention will be described in detail with reference to FIGS. 1 to 4.

1 and 2, the'iron chelate wet desulfurizer for removing high concentration hydrogen sulfide' according to the present embodiment is indicated by reference numeral 100.

The'iron chelate wet desulfurizer for removing high concentration hydrogen sulfide' 100 includes, as shown in FIGS. 1 to 4, a chemical storage tank 10 in which an aqueous iron chelate solution is stored; A reaction tower (20) mounted on the chemical liquid storage tank (10) and supplied with a target odor gas containing a high concentration of hydrogen sulfide generated in the digester tank as an upward airflow; An iron chelate supply pump 30 for supplying an iron chelate aqueous solution stored in the chemical liquid storage tank 10 to the reaction tower 20; A sedimentation tank 50 for precipitating sulfur compounds contained in the supplied reaction solution by receiving the reaction solution of the iron chelate aqueous solution and the malodorous gas from the reaction tower 20 naturally; A regeneration tank 40 for discharging the regeneration liquid obtained by aeration treatment of the precipitation treatment reaction liquid discharged by precipitation treatment of sulfur compounds in the settling tank 50 to the chemical liquid storage tank 10; A dehydrator 60 that receives the sulfur compound precipitated in the sedimentation tank 50 and the sulfur compound, which is a scum layer floating on the liquid level, through a settling water discharge pump 61 for dehydration treatment, and then supplies a dehydration solution to the regeneration tank 40. ); The scum layer containing sulfur compounds floating as supernatant water in the settling tank 50 is overflowed to the side opening 51 provided in the settling tank 50 and sent to the dehydrator 60, and the lower liquid of the settling tank 50 is regenerated. Variable buoyancy type bulkhead means 70 discharged to the tank 40; And condensed water generated by heat exchange with the filtered gas discharged from the reaction tower 20 through the outlet 21a is supplied to the sedimentation tank 50 via the condensed water discharge line 81, and the filtered gas from which the condensed water has been removed is cleaned. It includes a heat exchanger 80 that is discharged to the outside as a gas.

The reaction tower 20 includes an inlet 21b of a target odor gas provided at a lower end to introduce odor gas; A lower polling layer 22 disposed above the inlet 21b of the target odor gas and inscribed in the reaction tower 20; An upper polling layer 24 disposed at a position higher than the polling layer 22 and inscribed with the reaction tower 20; An eliminator (26a) and a tester (26b) disposed at a position higher than the upper polling layer (24) and inscribed in the reaction tower (20); A plurality of lower nozzles 27a disposed between the lower polling layer 22 and the upper polling layer 24 to spray an aqueous iron chelate solution onto the lower polling layer 22; A plurality of upper nozzles (27b) disposed between the upper polling layer (24) and the eliminator (26a) to spray an aqueous iron chelate solution onto the upper polling layer (24); And the inlet is connected to circulate to the bottom of the reaction tower 20, and the outlet is connected to circulate in the liquid of the sedimentation tank 50, so that the reaction solution of the reaction tower 20 is transferred to the sedimentation tank 50 by gravity. It includes a reaction liquid return line 28 to be transferred.

The iron chelate supply pump 30, through the iron chelate supply line 31, the suction side is connected to the chemical solution of the chemical solution storage tank 10, and the discharge side is the plurality of lower nozzles 27a and the plurality of upper portions. It is connected to the nozzle 27b.

The settling tank 50 includes a hopper part 51 formed to flow with the settling tank 50 at the bottom of the settling tank 50; And a side opening 52 which is formed on an upper end of a wall of one side of the settling tank 50 to pass and receive a scum layer containing a sulfur compound that is overflowed by raising the liquid level of the settling tank 50 to a predetermined height level or higher.

The settling water discharge pump 61 is a hopper part 51 of the settling tank 50 through the side opening 52 and the sulfur compound discharge line 62 interposed between the hopper part 51 and the dehydrator 60. The sulfur compound precipitated in and the sulfur compound which is the scum layer introduced into the side opening 52 are supplied to the dehydrator 60.

The variable-type buoyancy barrier means (70) includes a pair of guide rails (71) that are erected and installed on the inner wall portion of the settling tank (50) disposed outside the hopper (51); A pair of brackets 72 mounted to be movable in the direction of gravity along the pair of guide rails 71; A rod 73 that is rotatably mounted at both ends of the pair of brackets 72 and extends in a horizontal direction and parallel to an upstream channel partition 40a that divides the regeneration tank 40 and the settling tank 50 ; When the upper side is mounted and suspended on the rod 73 and the liquid level of the settling tank 50 is higher than a predetermined level, the lower liquid of the settling tank 50 is lowered and discharged to the regeneration tank 40, and the A variable diaphragm 74 having a size and shape that prevents the scum layer containing sulfur compounds floating as supernatant water in the sedimentation tank 50 from being discharged to the regeneration tank 40 so that it overflows to the side opening 52; A pair of rods (75) having one end mounted at both ends of the rod (73) and extending in a direction facing the variable diaphragm (74); And a buoyancy ball 76 that is mounted at both ends of the pair of rods 75 and extends parallel to the rods 73.

The dehydrator 60 includes a sulfur compound storage tank 65 for storing the dewatered sulfur compound from the precipitation treatment reaction liquid introduced from the settling tank 50 via a dehydration sulfur compound discharge line 64; And in order to return the dehydration liquid from which the sulfur compounds have been removed to the sedimentation tank 50, the inlet is connected to the dehydrator 60, and the other end is present between the variable diaphragm 74 and the partition part 40a for the upstream passage. And a dehydration liquid return line 63 disposed in the precipitation treatment reaction liquid of the sedimentation tank 50 and interposed with a pump.

The regeneration tank 40 includes: a partition portion 40a for an upstream passage that divides the sedimentation tank 50 and the regeneration tank 40; A partition part (40d) for a downstream flow path that divides the chemical liquid storage tank (10) and the regeneration tank (40); And, between the partition portion for the upstream flow passage (40a) and the partition portion for the downstream flow passage (40d), the inner space of the regeneration tank 40 is divided into two inner spaces, the partition portion 40b for the middle and upper flow passage and the partition portion 40b for the middle and downstream flow passages. Including a partition (40c), and the upstream flow passage partition portion (40a), the downstream flow passage partition portion (40d), the middle and upper flow passage partition portion (40b) and the middle and downstream flow passage partition (40c), In the state of being fixed to the bottom of the regeneration tank 40 and standing upright so that the precipitation treatment reaction solution of the sedimentation tank 50 flows in a zigzag manner in the regeneration tank 40 and discharged into the chemical liquid storage tank 10, the regeneration It is fixed to one of the pair of wall portions facing each other of the jaw 40 and is spaced apart from the other wall portions.

In addition, the regeneration tank 40 has a suction side connected to the discharge side of the blower 41 disposed outside the regeneration tank 40 and the discharge side is connected to circulate in the liquid of the regeneration tank 40 so that the regeneration tank ( It includes a diffuser 42 disposed at the bottom of 40).

The'iron chelate wet desulfurizer for removing high concentration hydrogen sulfide' 100 configured as described above may be operated as follows.

First, by operating the iron chelate supply pump 30, the chemical liquid storage tank 10 on the lower polling layer 22 and the upper polling layer 24 by the lower nozzle 27a and the upper nozzle 27b. By spraying the iron chelate aqueous solution stored in, the iron chelate aqueous solution penetrates and penetrates the lower and upper pauling layers 22 and 24, falls to the bottom of the reaction tower 20, and then returns the reaction solution. It is introduced into the sedimentation tank 50 via the Raan 28.

In this state, when a target odor gas containing high concentration hydrogen sulfide generated in a digester (not shown) flows into the lower portion of the reaction tower 20 through the target odor gas inlet 21b, the target odor gas is As a rising air flow, while sequentially penetrating the lower and upper polling layers 22 and 24, the eliminator is sequentially contacted with the iron chelate aqueous solution to collect and remove sulfur components contained in the odor gas. It is entered in (26a).

The odor gas to be treated entering the eliminator 26a sequentially passes through the eliminator 26a and the demister 26b, and is discharged to the outside of the reaction tower 20 via the outlet 21a. And, the sprayed iron chelate aqueous solution in which the sulfur component is collected naturally falls, passes through the upper and lower polling layers 24 and 22, falls to the bottom of the reaction tower 20, and then returns to the reaction solution. It is introduced into the sedimentation tank 50 via 28.

The odor gas filtered in the reaction tower 20 via the outlet 21a passes through a heat exchanger 80 to condense the gas component of the iron chelate aqueous solution that collects sulfur contained in the odor gas, and the condensate water discharge line It is supplied to the sedimentation tank 50 via 81, and the gaseous component of the malodorous gas filtered without condensation is released to the atmosphere as a clean gas.

In the precipitation-treated sulfur-containing iron chelate aqueous solution introduced into the sedimentation tank 50, the sulfur component is precipitated at the bottom of the sedimentation tank 50 and collected as a precipitate in the hopper part 51, and iron, which is supernatant water not containing sulfur, The sulfur-containing scum layer in the chelate aqueous solution floats on the liquid surface.

In this state, when the sulfur-containing iron chelate aqueous solution stored in the sedimentation tank 50 rises to a higher level than the side port 52, the sulfur-containing scum layer floating on the liquid surface flows through the side port 52, and the dehydrator ( 60) is supplied to the dehydration treatment, and the sulfur component precipitated and collected in the hopper unit 51 is supplied to the dehydrator 60 through the sediment water discharge pump 61 to be dewatered, and flows into the sedimentation tank 50 The lower solution of the iron chelate aqueous solution subjected to the precipitation treatment passes under the variable diaphragm 74 and into the regeneration tank 40 through an opening formed next to the partition portion 40a for the upstream passage of the regeneration tank 40. Will be released.

The sulfur-containing scum layer and precipitate supplied to the dehydrator 60 are dehydrated and stored in a sulfur compound storage tank (not shown), and the dehydration liquid is precipitated in the sedimentation tank 50 via the dehydration liquid return line 63. After being combined with the lower solution of the iron chelate aqueous solution, it is discharged into the regeneration tank 40 through an opening formed next to the partition portion 40a for the upstream passage of the regeneration tank 40.

While the precipitation treatment iron chelate aqueous solution discharged to the regeneration tank 40 comes into contact with the air supplied through the air diffuser 42 by the operation of the blower 41 and undergoes aeration treatment (oxidation and reduction treatment), The openings formed next to the partition portion 40b for the middle and upper flow passage, the partition portion 40c for the middle and downstream flow passage, and the partition portion 40d for the downstream flow passage pass through the openings in a zigzag manner to the chemical liquid storage tank 10 Will be released.

The'iron chelate wet desulfurizer for removing high-concentration hydrogen sulfide' constructed and operated as described above is applied to odor gas containing a large amount of hydrogen sulfide, such as a digester, and can efficiently provide sulfur from odor gas intensively. , In addition, the neutralization process is excluded, preventing the nozzle that supplies the chemical solution to the odor gas from being clogged because it does not generate salt, eliminating the work of periodically cleaning the nozzle, significantly reducing maintenance costs, as well as iron chelate, a chemical solution. By regenerating and reusing the aqueous solution, operation cost can be reduced.

10: chemical storage tank, 20: reaction tower, 21a: outlet, 21b: inlet of odor gas to be treated, 22: lower polling layer, 24: upper polling layer, 26a: eliminator, 26b: demister, 27a: lower nozzle, 27b: upper nozzle, 28: reaction liquid return line, 30: iron chelate supply pump, 31: iron chelate supply line, 40: regeneration tank, 40a: partition for upstream flow passage, 40b: partition for mid-upstream flow passage, 40c: middle-lower Divider for flow passage, 40d: divider for downstream passage, 41: blower, 42: diffuser, 50: sedimentation tank, 51: hopper part, 52: side port, 60: dehydrator, 61: sediment water discharge pump, 62: sulfur compound Discharge line, 63: dehydration liquid return line, 64: sulfur compound discharge line, 65: sulfur compound storage tank, 70: variable buoyancy bulkhead means, 71: a pair of guide rails, 72: a pair of brackets, 73: rod, 74: variable Diaphragm, 75: a pair of rods, 76: buoyancy port, 80: heat exchanger, 81: condensate discharge line, 100: iron chelate wet desulfurizer to remove high concentration hydrogen sulfide

Claims (5)

A chemical storage tank 10 in which an aqueous iron chelate solution is stored;
A reaction tower (20) mounted on the chemical liquid storage tank (10) and supplied with a target odor gas containing a high concentration of hydrogen sulfide generated in the digester tank as an upward airflow;
An iron chelate supply pump 30 for supplying an iron chelate aqueous solution stored in the chemical liquid storage tank 10 to the reaction tower 20;
A sedimentation tank 50 for precipitating sulfur compounds contained in the supplied reaction solution by receiving the reaction solution of the iron chelate aqueous solution and the malodorous gas from the reaction tower 20 naturally;
A regeneration tank 40 for discharging the regeneration liquid obtained by aeration treatment of the precipitation treatment reaction liquid discharged by precipitation treatment of sulfur compounds in the settling tank 50 to the chemical liquid storage tank 10;
A dehydrator 60 that receives the sulfur compound precipitated in the sedimentation tank 50 and the sulfur compound, which is a scum layer floating on the liquid level, through a settling water discharge pump 61 for dehydration treatment, and then supplies a dehydration solution to the regeneration tank 40. );
The scum layer containing sulfur compounds floating as supernatant water in the settling tank 50 is overflowed to the side opening 52 provided in the settling tank 50 and sent to the dehydrator 60, and the lower liquid of the settling tank 50 is regenerated. Variable buoyancy type bulkhead means 70 discharged to the tank 40; And
Condensed water generated by heat exchange with the filtered gas discharged from the reaction tower 20 through the outlet 21a is supplied to the sedimentation tank 50 via the condensed water discharge line 81, and the filtered gas from which the condensed water has been removed is supplied as a clean gas. Iron chelate wet desulfurizer for removing high concentration hydrogen sulfide, characterized in that it comprises a heat exchanger 80 that is discharged to the outside. The method of claim 1,
The reaction tower 20,
A target odor gas inlet 21b provided at the lower end to introduce odor gas;
A lower polling layer 22 disposed above the inlet 21b of the target odor gas and inscribed in the reaction tower 20;
An upper polling layer 24 disposed at a position higher than the lower polling layer 22 and inscribed with the reaction tower 20;
An eliminator (26a) and a tester (26b) disposed at a position higher than the upper polling layer (24) and inscribed in the reaction tower (20);
A plurality of lower nozzles 27a disposed between the lower polling layer 22 and the upper polling layer 24 to spray an aqueous iron chelate solution onto the lower polling layer 22;
A plurality of upper nozzles (27b) disposed between the upper polling layer (24) and the eliminator (26a) to spray an aqueous iron chelate solution onto the upper polling layer (24); And
The inlet is connected to circulate to the bottom of the reaction tower 20, and the outlet is connected to circulate in the liquid of the sedimentation tank 50, and the reaction solution of the reaction tower 20 is transferred to the settling tank 50 by gravity. It includes a reaction solution return line (28),
The iron chelate supply pump 30, through the iron chelate supply line 31, the suction side is connected to the chemical solution of the chemical solution storage tank 10, and the discharge side is the plurality of lower nozzles 27a and the plurality of upper portions. An iron chelate wet desulfurizer for removing high-concentration hydrogen sulfide, which is connected to the nozzle 27b. The method of claim 1,
The settling tank 50 includes a hopper part 51 formed to flow with the settling tank 50 at the bottom of the settling tank 50; And a side opening 52 formed on an upper end of a wall of one side of the settling tank 50 to pass and receive a scum layer containing a sulfur compound that rises above a predetermined level of the settling tank 50 and overflows,
The settling water discharge pump 61 is a hopper part 51 of the settling tank 50 through the side port 52 and the sulfur compound discharge line 62 interposed between the hopper part 51 and the dehydrator 60. ) And a sulfur compound that is a scum layer introduced into the side opening 52 to the dehydrator 60. Iron chelate wet desulfurizer for removing high concentration hydrogen sulfide. The method of claim 3,
The variable buoyancy-type partition wall means 70,
A pair of guide rails 71 that are erected and installed on the inner wall of the sedimentation tank 50 disposed outside the hopper part 51;
A pair of brackets 72 mounted to be movable in the direction of gravity along the pair of guide rails 71;
A rod 73 that is rotatably mounted at both ends of the pair of brackets 72 and extends in a horizontal direction and parallel to an upstream channel partition 40a that divides the regeneration tank 40 and the settling tank 50 ;
When the upper side is mounted and suspended on the rod 73 and the liquid level of the settling tank 50 is higher than a predetermined level, the lower liquid of the settling tank 50 is lowered and discharged to the regeneration tank 40, and the A variable diaphragm 74 having a size and shape that prevents the scum layer containing sulfur compounds floating as supernatant water in the sedimentation tank 50 from being discharged to the regeneration tank 40 so that it overflows to the side opening 52;
A pair of rods (75) having one end mounted at both ends of the rod (73) and extending in a direction facing the variable diaphragm (74); And a buoyancy sphere 76 that is mounted at both ends of the pair of rods 75 and extends parallel to the rods 73,
The dehydrator 60 is
A sulfur compound storage tank 65 for storing the dewatered sulfur compound from the precipitation treatment reaction liquid introduced from the settling tank 50 via the sulfur compound discharge line 64; And
In order to return the dehydration liquid from which the sulfur compound has been removed to the sedimentation tank 50, the inlet is connected to the dehydrator 60, and the other end is present between the variable diaphragm 74 and the partition part 40a for the upstream passage. Iron chelate wet desulfurizer for removing high concentration hydrogen sulfide, characterized in that it comprises a dehydration liquid return line (63) disposed in the precipitation treatment reaction liquid of the settling tank (50) and a pump interposed therebetween. The method of claim 1,
The regeneration tank 40,
A partition part (40a) for an upstream flow path that divides the sedimentation tank (50) and the regeneration tank (40);
A partition part (40d) for a downstream flow path that divides the chemical liquid storage tank (10) and the regeneration tank (40); And
Between the upstream flow passage partition 40a and the downstream flow passage partition 40d, the middle and upper flow passage partition 40b and the middle and downstream flow passage divide the inner space of the regeneration tank 40 into two inner spaces. Contains (40c), and
The upstream flow passage partition portion 40a, the downstream flow passage partition portion 40d, the middle and upper flow passage partition portion 40b, and the middle and downstream flow passage partition 40c,
In the state of being fixed on the bottom of the regeneration tank 40 and standing upright so that the precipitation treatment reaction solution of the sedimentation tank 50 flows in a zigzag manner in the regeneration tank 40 and discharged to the chemical liquid storage tank 10 It is fixed to one of a pair of wall parts facing each other of the regeneration tank 40 and spaced apart from any other wall part,
The regeneration tank 40 has a suction side connected to the discharge side of the blower 41 disposed outside the regeneration tank 40, and the discharge side is connected to circulate in the liquid of the regeneration tank 40, so that the regeneration tank 40 Iron chelate wet desulfurizer for removing high concentration hydrogen sulfide, characterized in that it comprises a diffuser (42) disposed on the bottom of the.

Images