KR101349424B1 - Purification apparatus of biogas and control method thereof - Google Patents

Abstract

A purification device for biogas of the present invention controls the operation of an absorption module by the methane concentration of the biogas, and collects and recirculates bio-methane generated when the methane concentration is short for improving the quality of the final bio-methane. The decrease of purification capacity of the device by the change of temperature in atmosphere or biogas is prevented for improving the purification capacity, increasing the production amount of bio-methane, and improving the quality of bio-methane. [Reference numerals] (10) Blower; (2) Anaerobic extinguishing tank; (21) Desulfurization tower; (22) Compressor; (23) Filter; (30) First cooler; (32) Second cooler; (40) Absorption module (PSA); (61) Concentration sensing module; (62) Temperature sensing module; (AA) Impurity gas; (BB) CO_2, a part of CH_4; (CC) Bio-methane; (DD) Storage tank; (EE) Recirculation

Description

Purification Apparatus and Control Method of Biogas

The present invention relates to a purification apparatus for biogas and a control method thereof, and more particularly, to a biogas purification apparatus capable of actively responding to the temperature and methane concentration of biogas, thereby producing higher quality biomethane, and The control method is related.

In general, high concentration organic waste such as biomass waste, energy crops and sewage sludge produces biogas in anaerobic digesters. The biomass waste includes food waste, livestock manure, slaughter waste and Palm Oil Mil Effluent (POME). The main components of the biogas are methane and carbon dioxide, and a small amount of impurities such as ammonia, hydrogen, nitrogen, volatile organic compounds, and siloxane, including hydrogen sulfide (H ₂ S). Among the biogas, methane (CH ₄ ) is a combustible material and can be used as an energy source such as city gas or vehicle fuel. Therefore, there is a growing interest in the purification technology of biogas for removing impurities other than methane contained in the biogas. The biogas refining technology removes impurities such as hydrogen sulfide (H ₂ S), siloxane, water, and fine particles contained in the biogas, and converts CO ₂ into a high quality fuel having high methane (CH ₄ ) content. It is a technology that converts and utilizes it as vehicle fuel and city gas.

However, since the conventional biogas purification apparatus sets the reference methane concentration of the source gas, operates the purification apparatus only when the methane concentration is higher than the reference concentration, and does not operate the purification apparatus when the methane concentration is lower than the reference concentration. There is a problem of low productivity because the operation of the device is very limited.

In addition, there is a problem that fluctuations in the purification performance of the biogas according to the atmospheric temperature. In particular, in summer, the purification performance is very low, there is a problem that the productivity is lowered and does not meet the quality standards of biomethane.

Korean Patent Registration No. 10-0985911 discloses a biogas pretreatment system.

SUMMARY OF THE INVENTION An object of the present invention is to provide a biogas purification apparatus and a control method thereof which can improve productivity and quality of biomethane regardless of a change in methane concentration and temperature of biogas.

The purification apparatus of a biogas according to the present invention includes a blower for supplying biogas from an anaerobic digester, a purifying module for purifying impurities contained in the biogas supplied from the blower, and a pressure from the biogas purified in the purifying module. Adsorption module for separating biomethane using a pressure swing adsorption method, a concentration detection module for detecting the methane concentration of the biogas flowing into the blower, and the methane concentration detected by the concentration detection module is less than the set concentration In this case, it includes a control module for reducing the cycle time of the adsorption module.

According to another aspect of the present invention, there is provided a purification apparatus for biogas, comprising: a detection module for detecting methane concentration and temperature of the biogas supplied from an anaerobic digester, a blower for supplying biogas from the anaerobic digester, and the detection module; A first cooler for cooling the biogas supplied from the blower according to the sensed temperature, a desulfurization tower for removing sulfur components of the biogas supplied from the blower, a compressor for compressing the biogas from the desulfurization tower, Pressure fluctuation adsorption from the second cooler for cooling the biogas from the compressor according to the temperature sensed by the sensing module, the filter for purifying impurities from the biogas passing through the second cooler, and the biogas purified from the filter. Adsorption module for separating biomethane using Pressure Swing Adsorption The control module controls the cycle time of the adsorption module according to the methane concentration of the biogas detected by the sensing module, and controls the operation of the first cooler and the second cooler according to the temperature of the biogas detected by the sensing module. It includes.

The control method of the biogas purification apparatus according to the present invention includes a concentration measurement step of measuring the methane concentration of the biogas flowing from the anaerobic digester, a purification step of purifying the biogas, and pressure fluctuation adsorption from the purified biogas. It includes an adsorption step of separating the methane using the (Pressure Swing Adsorption) method, and controls the cycle time of the adsorption step according to the methane concentration of the biogas measured in the concentration measurement step.

The biogas purification apparatus according to the present invention controls the operation of the adsorption module according to the methane concentration of the biogas, and recovers and recycles the biomethane produced when the methane concentration is lower, thereby improving the quality of the final produced biomethane. Can be.

In addition, when the content of methane first introduced is low, since the production of high quality biomethane is possible by recovering and recycling the biomethane, the operating range of the purification apparatus can be extended, and thus the production of biomethane can be increased. In addition, the quality of biomethane can be further improved.

In addition, since deterioration of the purification performance due to the change of the atmospheric temperature or the temperature of the biogas can be prevented, the purification performance can be improved to increase the production of biomethane, and the quality of the biomethane can be further improved.

1 is a schematic configuration diagram of an apparatus for purifying biogas according to an embodiment of the present invention.
FIG. 2 is a block diagram showing a control flow of the biogas purification apparatus shown in FIG. 1.
3 is a graph showing a cycle time change of the adsorption module according to the methane concentration of the biogas in the purification apparatus shown in FIG. 1.
4 is a flowchart illustrating a control method of a biogas purification apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail for the biogas purification apparatus according to an embodiment of the present invention.

1 is a schematic configuration diagram of an apparatus for purifying biogas according to an embodiment of the present invention. FIG. 2 is a block diagram showing a control flow of the biogas purification apparatus shown in FIG. 1.

1 and 2, the purification apparatus of the biogas according to the embodiment of the present invention, anaerobic digestion tank 2, blower 10, purification module 20, adsorption module 40, concentration detection module ( 61), the temperature sensing module 62, the cooler 30 and the control module 50.

The anaerobic digester 2 is a tank used for treating high concentration organic waste such as biomass waste, energy crops and sewage sludge. The anaerobic digester 2 ferments the organic waste to produce biogas containing methane, carbon dioxide, hydrogen sulfide, siloxane and the like.

The blower 10 is a device for supplying the gas produced in the anaerobic digester 2 to the purification module 20.

The purification module 20 purifies impurities such as water, hydrogen sulfide, and siloxane contained in the biogas supplied by the blower 10. The purification module 20 includes, for example, a desulfurization tower 21, a compressor 22, and a filter 23, but is not limited thereto, and further includes a water remover for removing moisture from the biogas. It may include.

The desulfurization tower 21 removes hydrogen sulfide (H ₂ S) contained in the biogas.

The compressor 22 boosts the biogas from which the hydrogen sulfide component has been removed.

The filter 23 may receive the biogas boosted by the compressor 22 and remove impurities such as fine dust included in the biogas.

The adsorption module 40 is also called an adsorption tower, and may be composed of a plurality of adsorption towers. The adsorption module 40 is a pressure swing adsorption (PSA) module is used. The pressure swing adsorption module is used to separate or purify a gas by separating or removing a specific component from a gas mixture through pressure fluctuation. As the mixed gas passes through the adsorption bed filled with carbon molecular sieve (CMS) under high pressure, the high selectivity components are adsorbed first, and the remaining components are discharged out of the adsorption bed. The pressure in the adsorption bed is regenerated to remove the adsorbed components. That is, the pressure swing adsorption module performs the pressure, production, pressure reduction and regeneration steps. In this embodiment, the carbon dioxide is adsorbed in the adsorption module 40, the biomethane from which carbon dioxide is removed can be produced.

3 is a graph showing a cycle time change of the adsorption module according to the methane concentration of the biogas in the purification apparatus shown in FIG. 1.

Referring to FIG. 3, the pressure swing adsorption method includes a pressurization step, a production step, a depressurization step, and a regeneration step, and the adsorption module 40 repeats a series of processes including the four steps. Can be obtained continuously. The time taken for one adsorption tower of the adsorption module 40 to go through one of the pressurization step, the production step, the decompression step, and the regeneration step is called swing time. Is completed, and the time taken to go through the four steps is called a cycle time. The control module described later controls the swing time of the adsorption module 40 according to the methane concentration detected by the concentration sensing module 61 described later. If the swing time is adjusted, the cycle time is also adjusted.

The concentration detection module 61 is a sensor for measuring the methane concentration of the biogas flowing into the blower 10. The concentration sensing module 61 is installed on a supply flow path connecting the anaerobic digester 2 and the blower 10.

The temperature sensing module 62 measures the temperature of the biogas supplied from the anaerobic digester 2. The temperature sensing module 62 is installed on a supply flow path connecting the anaerobic digester 2 and the blower 10.

The cooler 30 is provided in the purification module 20 to cool the biogas. The cooler 30 may include a first cooler 31 for cooling the biogas before flowing into the desulfurization tower 21 and a second cooler 32 for cooling the biogas from the compressor 22. Include. The first cooler 31 is a cooler that cools the biogas by exchanging the biogas and a cooling fluid, and the second cooler 32 is a chiller different from the first cooler 31. Is used as an example. Since the compression of the gas is generated while passing through the blower 10 and the compressor 22, and the temperature of the biogas is increased, the cooler 30 is formed at each rear end of the blower 10 and the compressor 22. It is provided. Since the heat generated by the compressor 22 is greater than the heat generated by the blower 10, a second cooler 32 provided at the rear end of the compressor 22 is provided at the rear end of the blower 10. The cooling performance is set to be better than that of the first cooler 31 being. Therefore, a chiller is used as the second cooler 32 and a cooler is used as the first cooler 31.

The control module 50, the adsorption module 40, the first cooler 31 and the second cooler 32 according to the values detected by the concentration detection module 61 and the temperature detection module 62. Control the operation of

If the methane concentration detected by the concentration detection module 61 is less than the predetermined concentration, the control module 50 recovers at least some of the biomethane separated from the adsorption module 40 and recycles it to the blower. In addition, the control module 50 reduces the swing time or cycle time of the adsorption module 40 when the methane concentration sensed by the concentration detection module 61 is less than a predetermined concentration. Here, the set concentration means the concentration of methane in the biogas introduced from the anaerobic digester (2), it will be described as an example of about 40 ~ 60 vol%.

In addition, the control module 50 selectively operates at least one of the first cooler 31 and the second cooler 32 according to the temperature sensed by the temperature sensing module 62.

Referring to the control method of the biogas purification apparatus according to an embodiment of the present invention configured as described above are as follows.

Referring to FIG. 4, first, when the blower 10 is operated, biogas is introduced from the anaerobic digester 2. (S1)

When the biogas is introduced, the concentration sensing module 61 and the temperature sensing module 62 measure the methane concentration of the biogas and the temperature of the biogas, respectively (S2).

Variation in the purification performance of biogas is severe depending on the atmospheric temperature, and in particular, the purification performance is deteriorated in summer. Therefore, by measuring the temperature change of the biogas, it is possible to adjust the operating conditions of the purification apparatus according to the temperature of the biogas.

The control module 50 compares the temperature of the biogas with a preset first preset temperature (S3).

If the temperature of the biogas is greater than or equal to the first predetermined temperature, the control module 50 operates both the first cooler 31 and the second cooler 32 (S4).

When the first cooler 31 is operated, the biogas introduced by the blower 10 is cooled while passing through the first cooler 31.

The biogas cooled in the first cooler 31 is supplied to the desulfurization tower 21 to remove hydrogen sulfide components from the desulfurization tower 21. Desulfurization performance is lowered as the temperature of the biogas flowing into the desulfurization tower 21 is higher. In this embodiment, since the biogas is cooled in the first cooler 31 and then supplied to the desulfurization tower 21, the desulfurization performance may be further improved.

The biogas from which the hydrogen sulfide component is removed from the desulfurization tower 21 is compressed by the compressor 22. (S6) The biogas is compressed while passing through the compressor 22, and the temperature is increased. The biogas compressed by the compressor 22 is cooled while passing through the second cooler 32. (S7)

The biogas cooled in the second cooler 32 passes through the filter 33, and the remaining impurities are removed. (S8) In the filter 33, if the temperature of the incoming biogas is high, the filter performance may decrease. have. In the present embodiment, since the biogas is cooled in the second cooler 32 and then flows into the filter 33, deterioration of the filter performance can be prevented.

On the other hand, the control module 50 compares the methane concentration of the biogas detected by the concentration detection module 61 with a predetermined set concentration (S9).

FIG. 3A illustrates a cycle time when the methane concentration of the biogas is high, and FIG. 3B illustrates a cycle time when the methane concentration of the biogas is low.

If the methane concentration of the biogas detected by the concentration detection module 61 is less than the set concentration, the cycle time of the adsorption module 40 is reduced. Reducing the cycle time corresponds to reducing the swing time corresponding to the pressurization, production, decompression, and regeneration steps, respectively. The time to stay in the carbon molecular adsorbent (CMS) in the adsorption module 40 depends on the size of the molecule. For example, since the size of the molecule is smaller than that of carbon dioxide (CO2) in the case of methane (CH4), the time to pass through the carbon molecular adsorbent is faster than the carbon dioxide. On the other hand, if it is determined that the concentration of methane is less than the set concentration, since the amount of molecules of the methane is less than the existing state, the case where the carbon dioxide passes at the time set to pass the existing methane occurs. Therefore, it is possible to shorten the swing time to prevent the passage of carbon dioxide. Although the recovery rate of methane may be reduced by shortening the swing time, in the present invention, since methane is recycled, it is possible to produce high quality biomethane having high methane content without reducing the recovery rate of methane.

In the adsorption module 40, carbon dioxide contained in the biogas is adsorbed to generate methane gas. (S11)

Since the methane concentration of the biogas introduced from the anaerobic digester 2 is less than the set concentration, at least some of the generated biomethane is recycled. In the present embodiment, for example, at least a part of the generated biomethane is circulated to the inlet side of the blower 10. However, the present invention is not limited thereto, and at least some of the generated biomethane may be circulated between the blower 10 and the purification module 20 or to the suction side of the purification module 10.

When the biomethane is recycled to the inlet side of the blower 10, the incoming biogas and the biomethane may be mixed to improve the methane concentration. Therefore, the quality of biomethane generated after passing through the purification module 20 may be further improved.

On the other hand, if the methane concentration of the biogas sensed by the concentration detection module 61 is greater than or equal to the set concentration, it operates without changing the cycle time of the adsorption module 40. The biomethane produced by the adsorption module 40 may be discharged and used as city gas or vehicle fuel without circulating. At this time, the final produced biomethane has a methane concentration of about 95% or more.

On the other hand, when the temperature of the biogas sensed by the temperature sensing module 62 is less than the first set temperature, the control module 50 sets the temperature of the biogas to a second set temperature lower than the first set temperature. (S12)

That is, when the temperature of the biogas is less than the first set temperature and is greater than or equal to the second set temperature, the control module 50 stops the operation of the first cooler 31 and the second cooler 32. In this case, since the cooling performance of the second cooler 32 is better than that of the first cooler 31, only the second cooler 32 is operated to biogas. Can lower the temperature.

On the other hand, if the temperature of the biogas detected by the temperature sensing module 62 is lower than the second set temperature, the control module 50 determines that it is an appropriate temperature range that can sufficiently secure the purification performance of the biogas. Can be. Therefore, the control module 50 may turn off both the first and second coolers 31 and 32. (S14)

Therefore, the biogas supplied by the blower 10 may be introduced into the adsorption module 40 after desulfurization, compression, and purification without additional cooling.

As described above, by controlling the operation of the adsorption module 30 according to the methane content of the biogas, and by recovering and recycling the biomethane generated when the methane concentration is insufficient, the quality of the final produced biomethane can be further improved. .

On the other hand, in the past, the operating range was very limited to operate the purification apparatus only when the first inflow of methane content was about 50% or more. However, in the present invention, when the content of methane first introduced is low, biomethane can be recovered and recycled to produce high-quality biomethane, thereby increasing the operating range of the purification apparatus. Thus, not only the production of biomethane can be increased, but also the quality of biomethane can be further improved.

In addition, since deterioration of the purification performance due to the change of the atmospheric temperature or the temperature of the biogas can be prevented, the purification performance can be improved to increase the production of biomethane, and the quality of the biomethane can be further improved.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: blower 20: purification module
21: desulfurization tower 22: compressor
23: filter 30: cooler
31: first cooler 32: second cooler
40: adsorption module

Claims (13)

A blower for supplying biogas from the anaerobic digester;
A purification module for purifying impurities contained in the biogas supplied from the blower;
An adsorption module for separating the biomethane from the biogas purified by the purification module using a pressure swing adsorption method;
A concentration detecting module detecting a methane concentration of the biogas flowing into the blower;
A temperature sensing module sensing a temperature of the biogas supplied from the anaerobic digester;
A cooler provided in the purification module to cool the biogas;
And a control module for reducing a cycle time of the adsorption module when the methane concentration detected by the concentration sensing module is less than a predetermined concentration. The method according to claim 1,
The adsorption module,
A pressurizing step of pressurizing the inside of the adsorption bed filled with the carbon molecular adsorbent to pass biogas, a production step of producing biomethane passing through the adsorption bed, a depressurizing step of depressurizing the inside of the adsorption bed, and A regeneration step of removing carbon dioxide,
The control module, if the methane concentration detected by the concentration detection module is less than the set concentration, biogas purification apparatus for reducing the cycle time it takes to perform the pressurization, production, decompression and regeneration step in turn. The method according to claim 1,
The control module includes:
When the methane concentration detected by the concentration detection module is less than the set concentration, the biogas purification apparatus for recovering some or all of the biomethane separated from the adsorption module to recycle to the blower. delete The method according to claim 1,
The control module includes:
Purifying apparatus of the biogas to operate the cooler when the temperature detected by the temperature sensing module is more than the set temperature. The method according to claim 1,
The purification module includes a desulfurization tower for removing sulfur components of the biogas supplied from the blower, a compressor for compressing the biogas from the desulfurization tower, and a filter for purifying impurities from the biogas passing through the compressor. ,
The cooler comprises a first cooler for cooling the biogas before flowing into the desulfurization tower, and a second cooler for cooling the biogas from the compressor. The method of claim 6,
The control module includes:
And at least one of the first cooler and the second cooler according to the temperature sensed by the temperature sensing module. A sensing module for sensing methane concentration and temperature of the biogas supplied from the anaerobic digester;
A blower for supplying biogas from the anaerobic digester;
A first cooler cooling the biogas supplied from the blower according to the temperature sensed by the sensing module;
A desulfurization tower for removing sulfur components of the biogas supplied from the blower;
A compressor for compressing the biogas from the desulfurization tower;
A second cooler cooling the biogas from the compressor according to the temperature sensed by the detection module;
A filter for purifying impurities from the biogas having passed through the second cooler;
An adsorption module for separating biomethane from the biogas purified by the filter using a pressure swing adsorption method;
Control the cycle time of the adsorption module according to the methane concentration of the biogas detected by the sensing module, and controls the operation of the first cooler and the second cooler according to the temperature of the biogas detected by the sensing module. Biogas purification apparatus comprising a module. A concentration measuring step of measuring the methane concentration of the biogas flowing from the anaerobic digester;
A purification step of purifying the biogas;
An adsorption step of separating methane from the purified biogas using a pressure swing adsorption method;
It includes a temperature measuring step of measuring the temperature of the biogas flowing from the anaerobic digester,
Controlling the cycle time of the adsorption step according to the methane concentration of the biogas measured in the concentration measurement step, the control of the biogas purification apparatus for cooling the biogas according to the temperature of the biogas measured in the temperature measurement step Way. The method of claim 9,
If the methane concentration measured in the concentration measuring step is less than the set criteria, the control method of the biogas purification apparatus for reducing the cycle time of the adsorption step. The method of claim 9,
If the methane concentration measured in the concentration measuring step is less than the predetermined standard, the control method of the biogas purification apparatus for recovering some or all of the methane separated in the adsorption step to join the biogas flowing from the anaerobic digester. delete The method of claim 9,
In the purification step,
A first cooling process of cooling the biogas introduced from the anaerobic digester,
A desulfurization process for removing hydrogen sulfide from the biogas,
A compression process of compressing the biogas from the desulfurization process,
A second cooling process of cooling the biogas from the compression process,
And controlling the biogas purification apparatus to perform at least one of the first cooling process and the second cooling process when the temperature of the biogas measured in the temperature measuring step is equal to or greater than a predetermined temperature.

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