KR100870519B1 - A dry desulfurization machine - Google Patents

Abstract

A dry desulfurization machine is provided to lengthen service life and enhance removal efficiency of hydrogen sulfide by removing moisture included in the methane gas through receiver and preventing desulfurizing agent filled within the desulfurization tub from melting away with the moisture, and to use for a long time by removing the residual moisture in the methane gas by limestone filled under the desulphurizing agent. A receiver(10) is provided with the methane gas generated in the digestion tank and removes the moisture included in the provided methane gas. A desulfurization tub(30) is connected to the receiver by a gas exhausting tube and is provided with methane gas ejected from the receiver. The limestone(38) is laminated within the desulfurization tub, is neutralized by the moisture emitted from the upside of the desulfurization tub, and removes the residual moisture remained from the methane gas provided in the desulfurization tub. The desulphurizing agent(40) is laminated on the limestone and removes the hydrogen sulfide included in the methane gas. A methane gas exhaust line(44) is installed at the upper end of the desulfurization tub and discharges the methane gas of which the hydrogen sulfide is removed to a storage tank through the desulphurizing agent.

Description

Dry desulfurization machine

1 is a view showing a dry desulfurizer according to a preferred embodiment of the present invention.

FIG. 2 is a view showing in detail the configuration of the dry desulfurizer shown in FIG. 1. FIG.

<Description of the symbols for the main parts of the drawings>

10: Receiving Machine 12: Receiving Tank

18: Separator 20: Drain tube

22: hydraulic pressure generating tank 24: overflow pipe

30: desulfurization tank 36: nozzle

38: limestone 40: desulfurization agent

44: methane gas discharge pipe 46: storage tank

The present invention relates to a dry desulfurizer, and more particularly, it is included in methane gas as a desulfurizer filled in a desulfurization tank in a state in which water is contained in methane gas generated from wastewater of a sewage treatment plant by installing a receiver. It relates to a dry desulfurizer to remove hydrogen sulfide.

In general, wastewater from sewage treatment plants contains large amounts of residues (sludge) such as organic substances.

If the wastewater containing these residues is discharged without biological and chemical oxygen demand and suspended solids content reaching the environmental standard, soil or water will be contaminated.

Accordingly, the environmental pollution is reduced by discharging the residues (organic substances) in the wastewater to rivers, etc. in a purified state through biological, physical and chemical treatment.

However, when the organic material in the wastewater is treated by physical methods, the treatment effect is insignificant, and the chemical treatment method requires a lot of treatment costs along with water pollution. Recently, biological methods using microorganisms are mainly used. .

Representative equipment used in the biological method is a digester, and after the wastewater is introduced into the digester, the organic material contained in the wastewater is treated by the microorganism.

Meanwhile, methane gas, which is an environmentally friendly alternative energy source, is generated as a by-product in the process of treating organic materials as described above. The methane gas is stored in a gas holder (gas tank) in a state of removing hydrogen sulfide through a desulfurization unit, and then a boiler. It is recycled as an energy source such as a generator. At this time, the reason for removing hydrogen sulfide contained in methane gas through desulfurization is to prevent the corrosiveness of hydrogen sulfide from pipes and various related devices that transfer fluids in the process of using methane gas as an energy source.

Representative desulfurizers for removing the hydrogen sulfide include, for example, a wet desulfurizer and a dry desulfurizer.

The former wet desulfurizer is a device using the principle that the microorganisms living in the equipment are desulfurized by eating hydrogen sulfide (H ₂ S) in the process of passing methane gas into the equipment called the cartist scraper. However, such a wet desulfurizer is expensive to manufacture and install, and has a disadvantage of requiring a wide installation place. In addition, there is a disadvantage in that the structure is not easy to operate and maintain.

The latter dry desulfurizer is a device for removing hydrogen sulfide (H ₂ S) by filling a desulfurization agent, a hydrogen sulfide adsorbent (Fe ₂ O ₃ ), into a desulfurization tower. The structure is relatively simple, and thus is widely used in most sewage treatment plants. It is one of the cranes. However, the dry desulfurizer as described above has a disadvantage in that the desulfurization efficiency is not very high, and the desulfurization agent is frequently replaced.

In other words, the methane gas contains a large amount of water in addition to hydrogen sulfide. If the water is passed through a dry desulfurizer in a state in which such water is not removed, the desulfurization agent retains moisture, and in this process, the desulfurization agent decreases the porosity of the desulfurization agent and the moisture. As it is dissolved in the desulfurization efficiency is drastically lowered, so there was a need to replace the desulfurizer periodically.

Accordingly, an object of the present invention for solving the above problems is to provide a dry desulfurizer to pass through the desulfurizer in a state in which a receiver is installed in the dry desulfurizer to remove the water contained in the methane gas.

Another technical problem to be achieved by the present invention is to provide a dry desulfurizer to use a relatively low cost limestone in addition to the desulfurization agent.

Another technical problem to be achieved by the present invention is to provide a dry desulfurizer to remove the residual water contained in the methane gas with neutralization through the limestone.

The present invention for achieving the above object is a dry desulfurization apparatus for removing the water and hydrogen sulfide contained in the methane gas generated in the digester, receiving the methane gas generated in the digester, the water contained in the supplied methane gas A desulfurization tank connected to the receiver and the gas discharge pipe connected to the receiver and receiving the methane gas discharged from the receiver, and neutralized with the water flow stacked in the desulfurization tank and injected from the upper side of the desulfurization tank, are supplied to the desulfurization tank. Limestone to remove residual water remaining in the methane gas, desulfurization agent is deposited on the limestone to remove the hydrogen sulfide contained in the methane gas and methane gas from the hydrogen sulfide is removed at the top of the desulfurization tank to remove hydrogen sulfide Consisting of methane gas discharge pipe to discharge to the storage tank And it characterized in that it comprises a milk vetch.

The receiver is provided with a receiving tank receiving methane gas, and installed vertically in the receiving tank, the methane gas supplied to the receiving tank passes through, and the separation plate of the porous structure to filter out the water contained in the methane gas; It is preferable that the drain pipe is installed at the lower end of the receiving tank and is discharged from the separation plate and discharged to the bottom of the receiving tank.

A hydraulic pressure generating tank is connected to the drain pipe, and the hydraulic pressure generating tank is configured to be filled with water to prevent discharge of methane gas to the drain pipe by applying hydraulic pressure to the outlet of the drain pipe.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, the dry desulfurizer 100 to be implemented in the present invention includes a receiver 10 and a desulfurizer 30.

The receiver 10 is connected to the digester and the gas supply pipe of the previous process, the methane gas generated from the waste water of the digester is supplied through the gas supply pipe to remove the water contained in the methane gas.

2 is a view showing the configuration of the receiver in more detail.

As shown in FIG. 2, the receiver 10 includes a receiving tank 12, a separating plate 18, a drain pipe 20, and a hydraulic pressure generating tank 22.

The receiving tank 12 is a tank for receiving the gas produced in the digestion tank (not shown) through the gas supply pipe 5, and stores the water separated from the methane gas through the separation plate 18, one side An inline 14 to which the gas supply pipe 5 is connected is provided at an upper end, and an outline 16 for discharging methane gas from which water is removed is provided at the other side. One end of the gas discharge pipe 28 is connected to the outline 16, and the other end of the gas discharge pipe 28 is connected to one lower end of the desulfurization tank 32 constituting the desulfurizer 30.

The separating plate 18 is a plate installed across the inner center of the receiving tank 12 in a vertically erect state, and is manufactured in a porous plate structure in which a plurality of micropores 18a are formed on a front surface thereof. The separation plate 18 is primarily methane gas supplied through the in-line of the receiving tank 12, the methane gas passes through the fine pores (18a) of the separation plate 18, the outline The water discharged to (16), and the water contained in the methane gas is caught between the micropores (18a) to filter the water contained in the methane gas. The water filtered by the separator 18 is lowered to its own weight in the form of water droplets on the surface of the separator 18 and falls below the receiving tank 12.

The methane gas passing through the micropores 18a of the separation plate 18 is discharged to the outline 16 of the receiving tank 12 in the state where most of the water is removed, and then desulfurized through the gas discharge pipe 28. It is discharged to the tank (32).

The drain pipe 20 is installed at one lower end of the receiving tank 12, and after being filtered from the methane gas through the separation plate 18, when the water falling down the receiving tank 12 is raised a certain amount, it is external To discharge into the

The hydraulic pressure generating tank 22 is connected to the drain pipe 20 to store the water discharged from the receiving tank 12, the methane gas is discharged to the drain pipe 20 by using the water pressure of the water stored therein It is a means to block it.

Specifically, the drain pipe 20 is assembled so that the outlet of the drain pipe 20 is close to the bottom surface of the hydraulic pressure generating tank 22 in the state of vertically penetrating the hydraulic pressure generating tank 22, the hydraulic pressure generating tank ( The inside of 22) is configured to fill a certain amount of water (W).

Through the above configuration, the water pressure of the water W filled in the hydraulic pressure generating tank 22 is transmitted to the outlet 20a of the drain pipe 20, so that the moisture accumulated at the bottom of the receiving tank 12 is drained. 20 may be discharged to the hydraulic pressure generating tank 22, but the methane gas in the receiving tank 12 is not discharged to the drain pipe 20 by the hydraulic pressure applied to the outlet 20a of the drain pipe 20. It will not be. At this time, the fresh water amount of the water (W) to be filled in the hydraulic pressure generating tank 22 is preferably to have a fresh water enough to generate a pressure of pressure higher than the supply pressure of the methane gas supplied to the receiving tank (12). .

On the other hand, one side upper end of the hydraulic pressure generating tank 22 is further provided with an over-plug tube (24). The overflow tube 24 is the water discharged from the receiving tank 12 through the drain pipe 20 is continuously stored in the hydraulic pressure generating tank 22, and when a predetermined amount or more, it is discharged to the discharge pipe 25 The level of the hydraulic pressure generating tank 22 is always kept constant.

In addition, an auxiliary drain pipe 26 is further installed on the bottom surface of the receiving tank 12. The auxiliary drain pipe 26 discharges moisture accumulated in the bottom of the receiving tank 12 to the outside during the cleaning operation of the receiving tank 12.

On the other hand, the desulfurizer 30 is a device for removing hydrogen sulfide contained in the methane gas passing through the receiver 10.

Referring to FIG. 1, the desulfurizer 30 includes a desulfurization tank 32. The desulfurization tank 32 is a tank for receiving methane gas from which water is removed through the receiver 10, and at one lower end thereof, a gas supply pipe 28 connected to the outline 16 of the receiving tank 12 is provided. It is installed, and receives the methane gas passing through the receiving tank 12 through the gas supply pipe (28).

The methane gas supplied to the desulfurization tank 32 will be described later, but hydrogen sulfide is removed in the process of passing through the limestone 38 and the desulfurization agent 40 sequentially stacked in the desulfurization tank 32, and then the desulfurization tank. It is discharged to the storage tank 46 through the methane gas discharge pipe 44 is installed on one side top of (32).

The nozzle 36 is mounted on the upper end of the desulfurization tank 32. The nozzle 36 automatically sprays water every predetermined time so that the inside of the desulfurization tank 32 is not dried, thereby preventing the methane gas supplied into the desulfurization tank 32 from being exploded.

On the inner bottom of the desulfurization tank 32, a drain plate 34 having a porous structure is formed to be inclined at a predetermined angle. The drain plate 34 discharges water remaining in the water and methane gas injected into the desulfurization tank 32 to the outside while supporting the limestone stacked in the desulfurization tank 32.

The limestone 38 is stacked inside the desulfurization tank 32. The limestone 38 neutralizes the water sprayed into the desulfurization tank 32 through the nozzle 36 and the water remaining in the methane gas so as not to be acidified by hydrogen sulfide contained in the methane gas. Water and water neutralized through the limestone 38 are discharged to the outside through the drain plate 34 installed under the desulfurization tank 32.

The limestone 38 removes residual water remaining in the methane gas passing through the receiver 10 to prevent moisture from adsorbing to the desulfurization agent 40, thereby extending the service life of the desulfurization agent 40. In addition, the limestone 38 has an advantage that the unit price is relatively low compared to the desulfurization agent 40, thus reducing the amount of the desulfurization agent 40 can increase the price competitiveness.

The desulfurization agent 40 is stacked on the limestone 38. The desulfurization agent 40 removes hydrogen sulfide contained in the methane gas passing through the limestone 38. In this case, the desulfurization agent 40 may use various materials capable of reacting with hydrogen sulfide.

On the other hand, one side of the desulfurization tank 32 is provided with a methane gas discharge pipe 44, the methane gas discharge pipe 44 is passed through the limestone 38 and the desulfurization agent 40 in the desulfurization tank 32, hydrogen sulfide is The removed methane gas is discharged to the storage tank 46.

The methane gas discharged to the storage tank 46 is supplied to each use place and used as an energy source, and the remaining amount is supplied to a gas burner (not shown) to be incinerated.

On the other hand, the hoist 42 is installed on the upper end of the desulfurization tank 32 while being supported by the support 43. The hoist 42 is a means provided to lift these heavy materials so that the desulfurizing agent 40, limestone 38, and the like stacked in the desulfurization tank 32 can be replaced with new ones.

Hereinafter, the operation of the dry desulfurizer 100 according to the present invention will be described with reference to FIGS. 1 and 2.

The methane gas generated in the process of decomposing wastewater in the digester is supplied to the receiver 10 constituting the dry desulfurizer 100 of the present invention to remove water contained in the methane gas, and then the desulfurizer 30 ) To remove hydrogen sulfide contained in methane gas.

First, when the methane gas is supplied into the receiving tank 12 through the gas supply pipe 5, the supplied methane gas is applied to the front surface of the separating plate 18 in a process of colliding with the separating plate 18 in the receiving tank 12. After passing through the micropores (18a) formed in this process, the water contained in the methane gas does not pass through the micropores (18a) is formed in the form of water droplets (B) on the surface of the separator 18 , To fall to the bottom of the receiving tank 12 by its own weight.

Then, when a certain amount of moisture is filled to the bottom of the receiving tank 12, the drain pipe 20 is opened to discharge the water filled in the bottom of the receiving tank 12 to the hydraulic pressure generating tank 22. At this time, a predetermined amount of water is always filled in the hydraulic pressure generating tank 22, and the hydraulic pressure of the water filled in the hydraulic pressure generating tank 22 is transmitted to the outlet 20a of the drain pipe 20 to the receiving tank 12. It is possible to block the supplied methane gas is discharged to the drain pipe (20).

Next, when a predetermined amount or more of water is filled into the hydraulic pressure generating tank 22 through the drain pipe, the overflow tube 24 is opened to discharge moisture to keep the water level in the hydraulic pressure generating tank 22 constant. .

On the other hand, the methane gas passing through the separator plate 18 of the receiver 20 is desulfurized through the gas discharge pipe 28 connected to the outline 16 of the receiving tank 12 in a state where most of the water is removed. After being discharged to the bottom in the desulfurization tank 32 constituting the group 30, it passes through the limestone 38. At this time, the limestone 38 is neutralized to prevent the water remaining in the methane gas and the water injected through the nozzle 36 from being acidified by hydrogen sulfide contained in the methane gas so that the inside of the desulfurization tank 32 is not dried. do. The neutralized water through the limestone 38 passes through the porous drain plate 34 installed at the bottom of the desulfurization tank 32 and then is discharged to the outside.

Thereafter, the methane gas passing through the limestone 38 is completely removed from the hydrogen sulfide contained in the methane gas in the course of passing through the desulfurization agent 40 stacked on the limestone 38, and the methane gas from which the hydrogen sulfide is removed is After being discharged to the outside through the methane gas discharge pipe 44 installed on the upper end of the desulfurization tank 32 is stored in the storage tank 46, it is supplied to each place of use and used as an energy source.

As described above, the present invention is to remove the water contained in the methane gas through the receiver installed in the dry desulfurizer to prolong the service life of the desulfurizer by preventing the desulfurization agent filled in the desulfurization tank to be dissolved by water. It has an effect that can increase the removal efficiency of hydrogen sulfide.

In addition, the present invention has the effect that the desulfurization agent can be used for a longer time by removing the residual water remaining in the methane gas with the neutralization action of the limestone filled under the desulfurization agent.

Claims (3)

In the dry desulfurizer to remove the water and hydrogen sulfide contained in the methane gas from the digester, Receiving a methane gas generated from the digester and removing water contained in the supplied methane gas; A desulfurization tank 32 connected to the receiver 10 and a gas discharge pipe 28 to receive methane gas discharged from the receiver 10; A limestone 38 stacked in the desulfurization tank 32 to neutralize water sprayed from the upper side of the desulfurization tank 32 and to remove residual water remaining in the methane gas supplied to the desulfurization tank; A desulfurization agent (40) stacked on the limestone (38) and removing hydrogen sulfide contained in the methane gas; The desulfurizer 30 is installed on the top of the desulfurization tank 32 and includes a desulfurizer 30 composed of a methane gas discharge pipe 44 for discharging methane gas from which hydrogen sulfide is removed to the storage tank 46 through the desulfurization agent 40. Dry desulfurizer characterized in that. The method of claim 1, The receiver 10 is; A receiving tank 12 receiving methane gas; A separating plate 18 having a vertical structure in the receiving tank 12 and passing through the methane gas supplied to the receiving tank, and filtering out moisture contained in the methane gas; Dry desulfurizer characterized in that it comprises a drain pipe 20 is installed on the lower end of the receiving tank 12 and is caught in the separation plate (18) to discharge the water dropped to the bottom of the receiving tank (12). The method of claim 2, A hydraulic pressure generating tank 22 is connected to the drain pipe 20; The water pressure generating tank 22 is configured to be filled with water (W) to prevent the discharge of methane gas to the drain pipe 20 by applying a water pressure to the outlet (20a) of the drain pipe (20). Dry desulfurizer.

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