KR102132569B1 - System for bio gas combined heat power generator - Google Patents

Abstract

The present invention relates to a system for a combined heat power generator of biogas includes: a gas treatment unit that pre-treats biogas input through a biogas supply pipe; a gas mixer unit that mixes the biogas and air supplied through pretreatment from the gas treatment unit; a combined heat power generator that introduces mixed gas as the biogas and the air are mixed in the gas mixer unit; a first methane gas measuring unit interposed between the gas treatment unit and the gas mixer unit to sense the concentration of methane gas (CH_4) moving from the gas treatment unit to the gas mixer unit; a second methane gas measuring unit interposed between the gas mixer unit and the combined heat power generator to sense the concentration of methane gas (CH_4) in the biogas which moves from the gas mixer unit to the combined heat power generator; an air introduction unit connected with the gas mixer unit to introduce air into the gas mixer unit; an air filter unit interposed between the air introduction unit and the gas mixer unit to remove fine dust or dust from the air introduced into the air introduction unit; and a desulfurization device interposed between the second methane gas measuring unit and the combine heat power generator.

Description

System for biogas cogeneration generator {SYSTEM FOR BIO GAS COMBINED HEAT POWER GENERATOR}

The present invention relates to a system for a biogas cogeneration system, in particular, as a facility used in the field of biogas energy generation, sensing the concentration of biogas, controlling the concentration of biogas supplied to the cogeneration system, and including a dry desulfurization device. The present invention relates to a system for a biogas cogeneration system capable of removing sulfur components in biogas.

Recently, the utilization of biogas among renewable energy has become important. As raw materials for biogas, organic waste resources such as livestock manure, food waste liquid, and food waste are used as raw materials.

Biogas can be used as a raw material for generators. In particular, a combined heat power generator is essentially used to produce electricity and heat using biogas.

Cogeneration generators are usually made by converting gas engines or diesel engines. Currently, generators based on biogas engines account for the largest portion of generators in the waste treatment field.

The concentration of biogas (CH ₄ ) generated by decomposition in anaerobic digestion is different for each zone, and biogas of different concentrations is supplied to a cogeneration generator with time.

This is because, in the process of operating the facility, the biogas concentration cannot be operated in accordance with prescribed standards.

However, the concentration of biogas required by the biogas cogeneration generator requires more than a certain standard. This is because certain criteria must be met to produce the electricity required.

Current technology converts methane gas (CH ₄ ) in biogas into thermal energy through blasting process to operate a generator to produce electricity, and some recover waste heat, which requires anaerobic digester heating or other heat. It is reused in the process.

Current, biogas cogeneration generator is required for more than the reference concentration, and the CH ₄ feed more than a reference concentration oversupply, CH ₄ of the over-fed biogas is incomplete combustion, and is discharged to the atmosphere through the excess gas burner That is true.

In other words, it uses only the required amount of heat and has a serious problem of wasting energy because it is all released into the atmosphere.

In order to solve such a problem, research and development of a device for detecting the concentration of biogas supplied through an NOx sensor of exhaust gas and mixing air and biogas has been sought.

However, the device for mixing air and biogas that has been studied has a problem in that the adjustment width is not large enough to adjust the width of the biogas concentration to be supplied above the reference concentration, and only the width of the very small concentration can be adjusted. .

In addition, the existing biogas cogeneration generator is operating at a minimum CH ₄ concentration of 50%. In addition, the gas mixer devices developed previously may be different for each site, but the concentration of CH ₄ is only 50% to 75%.

As a conventional technique, an invention such as Korean Registered Patent Publication No. 10-1464281 (invention name: biogas linked power generation system) has been proposed.

To solve the above-described problems of the present invention, and relates to a system for a biogas cogeneration system, in particular, as a facility used in the field of biogas energy generation, detecting the concentration of biogas, the amount of biogas concentration supplied to the cogeneration system It is to provide a system for a biogas cogeneration system that can control, remove sulfur components in biogas, including a dry desulfurization device, and maximize utilization efficiency of biogas.

In order to solve the above problems, the present invention is a gas treatment unit for pre-processing the biogas input through the biogas supply pipe; A gas mixer unit mixing biogas and air pre-treated and supplied from the gas street unit; A cogeneration generator in which biogas and air are mixed in the gas mixer unit and mixed gas is introduced; A first methane gas measuring unit which is formed between the gas stream unit and the gas mixer unit and detects the concentration of methane gas (CH ₄ ) in the biogas that is moved from the gas street unit to the gas mixer unit; A second methane gas measurement unit which is formed between the gas mixer unit and the cogeneration generator and detects the concentration of methane gas (CH ₄ ) in the biogas transferred from the gas mixer unit to the cogeneration generator; It is connected to the gas mixer unit, the air input unit for introducing air into the gas mixer unit; An air filter unit formed between the air input unit and the gas mixer unit, and performing a role of removing fine dust or dust from the air input from the air input unit; And a desulfurization device formed between the second methane gas measurement unit and the cogeneration generator.

In addition, the present invention can be connected to the system for selling the electricity generated by the cogeneration generator to Korea Electric Power Corporation. In addition, the present invention may be configured as a system for selling the electricity generated by the cogeneration generator to Korea Electric Power Corporation.

In addition, the present invention, the first methane gas measurement unit and the second methane gas measurement unit, the information about the methane gas (CH ₄ ) concentration measured by the control unit is transmitted, the control unit, the bio-input to the cogeneration control parts of the gas mixer, the amount of gas in the methane gas (CH ₄₎ concentration to be supplied to the set methane gas (CH ₄₎ concentration amount and wherein the gas mixer preset of methane gas in the (CH ₄₎ and the air and controlled so as to be mixed The first methane gas measurement unit measures the concentration of methane gas (CH ₄ ) supplied from the gas processing unit to the gas mixer unit by using a methane gas concentration meter installed on one side and transmits a signal to the control unit. 2 The methane gas measurement unit may measure the concentration of methane gas (CH ₄ ) supplied from the gas mixer unit to the cogeneration generator using a methane gas concentration meter installed on one side and transmit a signal to the control unit.

In addition, the present invention, the desulfurization device, by using activated carbon to adsorb and remove harmful substances in the biogas cartridge exchange type dry desulfurization device, the input of the biogas flow; An outlet connected to the generator so that the biogas introduced into the inlet is discharged to the generator; A first desulfurization gas moving part which is connected to the input part and the discharge part and reduces sulfur of the biogas and moves it to the discharge part; A second desulfurization gas moving part which is connected to the input part and the discharge part and reduces sulfur of the biogas and moves it to the discharge part; And a bypass passage unit configured to control the gas to be moved to only one of the first desulfurization gas moving unit and the second desulfurization gas moving unit, wherein the first desulfurization gas moving unit is connected to one side of the discharge unit and has a T-shape. A first gas passage intermediate crossing member formed of a pipe; A first gas passage moving member connected to one side of the first gas passage intermediate crossing member and formed of an elbow-shaped pipe; A second gas passage moving member connected to the first gas passage moving member and formed of a straight pipe; A third gas passage moving member connected to the second gas passage moving member and formed of a flexible material; A fourth gas passage moving member connected to the third gas passage moving member and having a larger diameter at the other end than a diameter at one end; A first body part connected to the other side of the fourth gas passage moving member and formed to have the same diameter as the diameter of the other end of the fourth gas passage moving member; A first activated carbon cartridge unit formed in a part of the inner space of the first body unit to desulfurize the sulfur component of the biogas; A second activated carbon cartridge unit formed on another portion of the inner space of the first body portion to desulfurize the sulfur component of the biogas; A fifth gas passage moving member connected to one side of the first body portion, the diameter of the other end being larger than that of one end, and the diameter of the other end having the same diameter as the diameter of the first body portion; A sixth gas passage moving member connected to the fifth gas passage moving member and formed of a flexible material; A seventh gas passage moving member connected to the sixth gas passage moving member and formed of a straight pipe; An eighth gas passage moving member connected to the seventh gas passage moving member and formed of an elbow-shaped pipe; Included in the ninth gas passage moving member is connected to the eighth gas passage moving member, formed of a straight pipe, and connected to the discharge portion, the second desulfurization gas moving part, the first gas passage intermediate A third gas passage intermediate crossing member connected to the crossing member and formed of a T-shaped pipe; A 21st gas passage moving member connected to one side of the third gas passage intermediate crossing member and formed of a straight pipe; A twenty-first gas passage moving member connected to the twenty-first gas passage moving member and formed of an elbow-shaped pipe; A 23rd gas passage moving member connected to the 22nd gas passage moving member and formed of a straight pipe; A 24th gas passage moving member connected to the 23rd gas passage moving member and formed of a flexible material; A 25th gas passage moving member connected to the 24th gas passage moving member and having a larger diameter at the other end than a diameter at one end; A second body part connected to the other side of the 25th gas passage moving member and formed to have the same diameter as the diameter of the other end of the 25th gas passage moving member; A third activated carbon cartridge unit formed in a part of the inner space of the second body unit to desulfurize the sulfur component of the biogas; A fourth activated carbon cartridge unit formed on another portion of the inner space of the second body portion to desulfurize the sulfur component of the biogas; A 26th gas passage moving member connected to one side of the second body part, the diameter of the other end being larger than that of one end, and the diameter of the other end being formed to have the same diameter as the diameter of the second body part; A 27th gas passage moving member connected to the 26th gas passage moving member and formed of a flexible material; A 28th gas passage moving member connected to the 27th gas passage moving member and formed of a straight pipe; A 29th gas passage moving member connected to the 28th gas passage moving member and formed of an elbow-shaped pipe; And a fourth gas passage intermediate crossing member connected to the 29th gas passage moving member, formed of a T-shaped pipe, and connected to the discharge part, wherein the bypass passage part includes the first desulfurization gas. A second gas passage intermediate crossing formed between the ninth gas passage moving member and the fourth gas passage intermediate crossing member and formed of a T-shaped pipe so that gas can be moved to only one of the eastern and second desulfurization gas moving parts absence; A tenth gas passage moving member connected to one side of the second gas passage intermediate crossing member and formed of a straight pipe; And an eleventh gas passage moving member formed between the third gas passage intermediate crossing member and the tenth gas passage moving member, and formed of a straight pipe. The bypass passage part includes the first desulfurization gas. A first valve part formed between the first gas passage intermediate crossing member and the first gas passage moving member so as to serve to move the gas to only one of the eastern and second desulfurization gas moving parts; A second valve part formed between the eighth gas passage moving member and the ninth gas passage moving member; A third valve part formed between the second gas passage intermediate crossing member and the fourth gas passage intermediate crossing member; A fourth valve part formed between the tenth gas passage moving member and the eleventh gas passage moving member; A fifth valve portion formed between the first gas passage intermediate crossing member and the third gas passage intermediate crossing member; A sixth valve portion formed between the 21st gas passage moving member and the 22nd gas passage moving member; And a seventh valve portion formed between the 29th gas passage moving member and the 4th gas passage intermediate crossing member.

In addition, the present invention, the first activated carbon cartridge portion, the first cartridge frame portion is formed in a long cylindrical shape; At least one first circular member formed inside the first cartridge frame portion; At least one mesh member formed to surround the outer diameter of the first cartridge frame portion; A gas passage member inside the first activated carbon cartridge which is provided on the first circular member formed on one side of the first cartridge frame part and changes the movement path of the biogas by the through hole; It is provided inside the first cartridge frame portion, is formed after the gas passage member inside the first activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the first activated carbon cartridge. A gas passage member inside the second activated carbon cartridge to change; It is provided inside the first cartridge frame portion, is formed next to the gas passage member inside the second activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the second activated carbon cartridge. A gas passage member inside the third activated carbon cartridge for changing; And a gas passage member inside the first activated carbon cartridge, formed after the gas passage member inside the third activated carbon cartridge, and moving path of biogas by the through hole with the through passage of the gas passage member inside the third activated carbon cartridge. It may include; a gas passage member inside the fourth activated carbon cartridge to change differently.

In addition, the present invention, the second activated carbon cartridge portion, the first cartridge frame portion is formed in a long cylindrical shape; At least one first circular member formed inside the first cartridge frame portion; At least one mesh member formed to surround the outer diameter of the first cartridge frame portion; A gas passage member inside the first activated carbon cartridge which is provided on the first circular member formed on one side of the first cartridge frame part and changes the movement path of the biogas by the through hole; It is provided inside the first cartridge frame portion, is formed after the gas passage member inside the first activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the first activated carbon cartridge. A gas passage member inside the second activated carbon cartridge to change; It is provided inside the first cartridge frame portion, is formed next to the gas passage member inside the second activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the second activated carbon cartridge. A gas passage member inside the third activated carbon cartridge for changing; And a gas passage member inside the first activated carbon cartridge, formed after the gas passage member inside the third activated carbon cartridge, and moving path of biogas by the through hole with the through passage of the gas passage member inside the third activated carbon cartridge. It may include; a gas passage member inside the fourth activated carbon cartridge to change differently.

In addition, the present invention, the third activated carbon cartridge portion, the first cartridge frame portion is formed to be elongated in a cylindrical shape; At least one first circular member formed inside the first cartridge frame portion; At least one mesh member formed to surround the outer diameter of the first cartridge frame portion; A gas passage member inside the first activated carbon cartridge which is provided on the first circular member formed on one side of the first cartridge frame part and changes the movement path of the biogas by the through hole; It is provided inside the first cartridge frame portion, is formed after the gas passage member inside the first activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the first activated carbon cartridge. A gas passage member inside the second activated carbon cartridge to change; It is provided inside the first cartridge frame portion, is formed next to the gas passage member inside the second activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the second activated carbon cartridge. A gas passage member inside the third activated carbon cartridge for changing; And a gas passage member inside the first activated carbon cartridge, formed after the gas passage member inside the third activated carbon cartridge, and moving path of biogas by the through hole with the through passage of the gas passage member inside the third activated carbon cartridge. It may include; a gas passage member inside the fourth activated carbon cartridge to change differently.

In addition, the present invention, the fourth activated carbon cartridge portion, the first cartridge frame portion is formed to be elongated in a cylindrical shape; At least one first circular member formed inside the first cartridge frame portion; At least one mesh member formed to surround the outer diameter of the first cartridge frame portion; A gas passage member inside the first activated carbon cartridge which is provided on the first circular member formed on one side of the first cartridge frame part and changes the movement path of the biogas by the through hole; It is provided inside the first cartridge frame portion, is formed after the gas passage member inside the first activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the first activated carbon cartridge. A gas passage member inside the second activated carbon cartridge to change; It is provided inside the first cartridge frame portion, is formed next to the gas passage member inside the second activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the second activated carbon cartridge. A gas passage member inside the third activated carbon cartridge for changing; And a gas passage member inside the first activated carbon cartridge, formed after the gas passage member inside the third activated carbon cartridge, and moving path of biogas by the through hole with the through passage of the gas passage member inside the third activated carbon cartridge. It may include; a gas passage member inside the fourth activated carbon cartridge to change differently.

The system for a biogas cogeneration generator according to an embodiment of the present invention can improve productivity by maximizing power generation efficiency by supplying a certain concentration of biogas by adjusting the gas mixing ratio of the biogas cogeneration generator.

In addition, the system for a biogas cogeneration generator according to an embodiment of the present invention can provide a system for a biogas cogeneration generator with an increase in power generation efficiency of 10 to 20% or more compared to a conventional biogas generator.

In addition, the system for a biogas cogeneration generator according to an embodiment of the present invention can reduce the concentration of gas discharged to the outside according to the optimum conditions of complete combustion, and thus has a great effect of preventing environmental pollution.

In addition, the system for a biogas cogeneration generator according to an embodiment of the present invention is formed as a structure of a bypass passage for controlling gas to be moved to only one of the first desulfurization gas moving unit and the second desulfurization gas moving unit, which is normally Even if a failure or a problem occurs while using one of the first desulfurization gas moving unit and the second desulfurization gas moving unit, the desulfurization gas of either the first desulfurization gas moving unit or the second desulfurization gas moving unit using a bypass passage unit It can provide an advantage that the utilization rate is 100% even in the period during which the moving part is repaired.

In addition, in order to maximize the desulfurization effect, the system for a biogas cogeneration generator according to an embodiment of the present invention may provide a device having a structure capable of improving a contact area so that the biogas can contact the desulfurization agent as much as possible.

In addition, the system for a biogas cogeneration generator according to an embodiment of the present invention can improve the residence time of the biogas in which the biogas flows inside the cartridge.

In addition, the system for a biogas cogeneration generator according to an embodiment of the present invention has an effect of preventing corrosion of a generator and connected machinery by removing the sulfur component of the biogas as much as possible.

In addition, in the system for a biogas cogeneration generator according to an embodiment of the present invention, as the sulfur component in the biogas supplied to the generator or boiler is removed, the generator or boiler is stabilized to reduce exhaust gas emissions and generation of dioxins. Can.

1 is a view showing a system for a biogas cogeneration generator according to an embodiment of the present invention.
Figure 2 is a view showing in detail the desulfurization device of the system for a biogas cogeneration generator according to an embodiment of the present invention.
Figure 3 is a view showing in detail the first activated carbon cartridge portion of the system for a biogas cogeneration generator according to an embodiment of the present invention.
4 is a view showing in detail the second activated carbon cartridge portion of the system for a biogas cogeneration generator according to an embodiment of the present invention.
5 is a view showing in detail the third activated carbon cartridge portion of the system for a biogas cogeneration generator according to an embodiment of the present invention.
6 is a view showing in detail the fourth activated carbon cartridge portion of the system for a biogas cogeneration generator according to an embodiment of the present invention.
7 is a view for explaining a first activated carbon cartridge portion, a second activated carbon cartridge portion, a third activated carbon cartridge portion and a fourth activated carbon cartridge portion of the system for a biogas cogeneration system according to an embodiment of the present invention.

Hereinafter, the description of the present invention with reference to the drawings is not limited to a specific embodiment, and various transformations may be applied and various embodiments may be provided. In addition, it should be understood that the contents described below include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention.

In the following description, terms such as first and second are terms used to describe various components, and are not limited in meaning to themselves, and are used only to distinguish one component from other components.

The same reference numerals used throughout this specification denote the same components.

The singular expression used in the present invention includes the plural expression unless the context clearly indicates otherwise. In addition, terms such as “include”, “have” or “have” described below are intended to designate the existence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification. It should be interpreted and understood to not preclude the existence or addition possibility of one or more other features, numbers, steps, actions, components, parts or combinations thereof.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 1 to 7.

1 is a view showing a system for a biogas cogeneration generator according to an embodiment of the present invention, and FIG. 2 is a view showing in detail a desulfurization device for a system for a biogas cogeneration generator according to an embodiment of the present invention.

In addition, Figure 3 is a view showing in detail the first activated carbon cartridge portion of the system for a biogas cogeneration generator according to an embodiment of the present invention, Figure 4 is a second activated carbon of the system for a biogas cogeneration generator according to an embodiment of the present invention It is a view showing in detail the cartridge unit, Figure 5 is a view showing in detail the third activated carbon cartridge unit of the system for a biogas cogeneration generator according to an embodiment of the present invention, Figure 6 is a biogas cogeneration according to an embodiment of the present invention It is a figure showing in detail the fourth activated carbon cartridge part of the air system.

7 is a view for explaining a first activated carbon cartridge unit, a second activated carbon cartridge unit, a third activated carbon cartridge unit, and a fourth activated carbon cartridge unit of the system for a biogas cogeneration system according to an embodiment of the present invention.

Referring to FIG. 1, the system 1 for a biogas cogeneration generator according to an embodiment of the present invention includes a gas street unit 600, a gas mixer unit 700, a first methane gas measurement unit 710, and a second It may include a methane gas measurement unit 720, the air input unit 800, the air filter unit 810, a cogeneration generator 900, a desulfurization device 1100 and a control unit (not shown).

For reference, the biogas (G) used in the present invention refers to biogas produced by anaerobic fermentation of organic waste.

In addition, the general definition of biogas (G) means a gas that is a mixed form of methane and carbon dioxide produced in biomass due to anaerobic digestion.

In addition, the organic waste here refers to any one or more wastes of animal manure, food waste liquid or food waste.

The gas treatment unit 600 may serve to pre-process the biogas (G) input through the biogas supply pipe.

The gas mixer unit 700 may perform a role of mixing the biogas (G) and air that is pre-processed and supplied from the gas treatment unit 600.

In the cogeneration generator 900, biogas and air are mixed in the gas mixer 700, and the mixed gas may be introduced. The cogeneration generator 900 may generate electricity by generating methane gas (CH ₄ ) in the biogas as a raw material.

In addition, the cogeneration generator 900 may be connected to a system for selling the produced electricity to the Korea Electric Power Corporation (1000). In this case, a renewable energy certificate (REC), which is a weight using biogas, in addition to the SMP that is sold in series, can be sold through a separate contract.

The first methane gas measurement unit 710 is formed between the gas treatment unit 600 and the gas mixer unit 700, the methane in the biogas is moved from the gas treatment unit 600 to the gas mixer unit 700 It may serve to sense the concentration of gas (CH ₄ ).

In addition, the first methane gas measurement unit 710 is a methane gas supplied from the gas treatment unit 600 to the gas mixer unit 700 using a methane gas concentration meter (not shown) installed on one side (CH ₄ ) The signal can be transmitted to a control unit (not shown) by measuring the concentration.

The second methane gas measurement unit 720 is formed between the gas mixer unit 700 and the cogeneration generator 900 to move from the gas mixer unit 700 to the cogeneration generator 900 methane gas in biogas (G) ( It can serve to detect the concentration of CH ₄ ).

In addition, the second methane gas measurement unit 720 uses the methane gas concentration meter (not shown) installed on one side to measure the concentration of methane gas (CH ₄ ) supplied from the gas mixer unit 700 to the cogeneration generator 900. The signal can be transmitted to a control unit (not shown) by measuring.

The air introduction unit 800 is connected to the gas mixer unit 700 and may serve to inject air into the gas mixer unit 700.

The air filter unit 810 is formed between the air input unit 800 and the gas mixer unit 700 and may serve to remove fine dust or dust from the air input from the air input unit 800.

The desulfurization device 1100 may remove the sulfur component in the biogas and supply it to the cogeneration generator 900. Accordingly, a stabilized gas may be supplied in connection with the operation of the cogeneration generator 900. Details of this will be described with reference to FIGS. 2 to 7 to be described later.

In addition, the present invention may include a control unit (not shown).

The control unit may receive or transmit information on the measured amount of methane gas (CH ₄ ) concentration from the first methane gas measurement unit 710 and the second methane gas measurement unit 720.

The controller may control the gas mixing unit 700 is supplied with methane gas (CH ₄₎ concentration of the amount of biogas (G) is set in the amount of methane gas (CH ₄₎ concentration is fed to the CHP generator 900.

In addition, the control unit may serve to control the mixture of methane gas (CH ₄ ) and air preset in the gas mixer unit 700.

2 to 7, the desulfurization device 1100 according to an embodiment of the present invention includes an input part 10, a first gas passage moving member 11, a second gas passage moving member 12, and a third gas passage Furnace moving member 13, fourth gas passage moving member 14, fifth gas passage moving member 15, sixth gas passage moving member 16, seventh gas passage moving member 17, eighth gas passage Furnace moving member 18, the ninth gas passage moving member 19, the first gas passage intermediate crossing member 21, the second gas passage intermediate crossing member 22, the third gas passage intermediate crossing member 23, 4th gas passage intermediate crossing member 24, 10th gas passage moving member 25, 11th gas passage moving member 26, 21st gas passage moving member 31, 22th gas passage moving member 32 , 23rd gas passage moving member 33, 24th gas passage moving member 34, 25th gas passage moving member 35, 26th gas passage moving member 36, 27th gas passage moving member 37 , 28th gas passage moving member 38, 29th gas passage moving member 39, first valve part 51, second valve part 52, third valve part 53, fourth valve part ( 54), the fifth valve portion 55, the sixth valve portion 56, the seventh valve portion 57, the discharge portion 60, the first body portion 70, the second body portion 80, the second 1 activated carbon cartridge unit 110, second activated carbon cartridge unit 120, third activated carbon cartridge unit 130, fourth activated carbon cartridge unit 140, first cartridge frame unit 210, first circular member 220 ), the mesh member 300, the through hole 400, the gas passage inside the activated carbon cartridge 500, the gas passage member inside the first activated carbon cartridge 510, the gas passage member inside the second activated carbon cartridge 520, the third It may include a gas passage member 530 inside the activated carbon cartridge and a gas passage member 540 inside the fourth activated carbon cartridge.

Biogas (G) may be introduced into the input unit 10.

The discharge unit 60 may be connected to the generator so that biogas introduced into the input unit 10 is discharged to the generator.

The first desulfurization gas moving part is connected to the input part 10 and the discharge part 60, and may serve to reduce the sulfur of the biogas G and move it to the discharge part 60.

The second desulfurization gas moving part is connected to the input part 10 and the discharge part 60, and may serve to reduce the sulfur of the biogas G and move it to the discharge part 60.

The bypass passage unit may serve to control the gas to be moved to only one of the first desulfurization gas moving unit and the second desulfurization gas moving unit.

Specifically, the first desulfurization gas moving unit is a first gas passage intermediate crossing member 21, a first gas passage moving member 11, a second gas passage moving member 12, a third gas passage moving member 13, 4th gas passage moving member 14, 5th gas passage moving member 15, 6th gas passage moving member 16, 7th gas passage moving member 17, 8th gas passage moving member 18, It may include a ninth gas passage moving member 19, the first body portion 70, the first activated carbon cartridge portion 110 and the second activated carbon cartridge portion 120.

The first gas passage intermediate crossing member 21 may be connected to one side of the discharge unit 60. In addition, the first gas passage intermediate crossing member 21 may be formed of a T-shaped pipe.

The first gas passage moving member 11 may be connected to one side of the first gas passage intermediate crossing member 21. In addition, the first gas passage moving member 11 may be formed of elbow-shaped piping.

The second gas passage moving member 12 may be connected to the first gas passage moving member 11. In addition, the second gas passage moving member 12 may be formed of a straight pipe.

The third gas passage moving member 13 may be connected to the second gas passage moving member 12. In addition, the third gas passage moving member 13 may be formed of a flexible material. In addition, the third gas passage moving member 13 may be formed in a flexible joint (flexible joint) joint method.

The fourth gas passage moving member 14 may be connected to the third gas passage moving member 13. In addition, the fourth gas passage moving member 14 may have a larger diameter at the other end than a diameter at one end. In addition, the diameter of the other end of the fourth gas passage moving member 14 may be formed to have the same diameter as the diameter of the first body portion 70.

The first body portion 70 may be connected to the other side of the fourth gas passage moving member 14. In addition, the first body portion 70 may be formed to have the same diameter as the diameter of the other end of the fourth gas passage moving member 14. In addition, the first body portion 70 may be formed to be long in the horizontal direction.

The first activated carbon cartridge unit 110 is formed in a part of the inner space of the first body unit 70, and may serve to desulfurize the sulfur component of the biogas. In addition, the first activated carbon cartridge unit 110 may serve to adsorb and remove harmful substances in biogas. In addition, the first activated carbon cartridge unit 110 may accommodate a polling (not shown) serving as activated carbon therein.

The second activated carbon cartridge unit 120 is formed on the other portion of the inner space of the first body unit 70, and may serve to desulfurize the sulfur component of the biogas. In addition, the second activated carbon cartridge unit 120 may serve to adsorb and remove harmful substances in biogas. In addition, the second activated carbon cartridge unit 120 may contain a polling (not shown) serving as activated carbon therein.

In addition, the second activated carbon cartridge unit 120 is preferably disposed in a step after the biogas passes through the first activated carbon cartridge unit 110.

The fifth gas passage moving member 15 may be connected to one side of the first body portion 70. In addition, the fifth gas passage moving member 15 may be formed to have a larger diameter at the other end than a diameter at one end, and a diameter at the other end having the same diameter as the diameter of the first body portion 70.

The sixth gas passage moving member 16 may be connected to the fifth gas passage moving member 15. Further, the sixth gas passage moving member 16 may be formed of a flexible material. In addition, the sixth gas passage moving member 16 may be formed by a flexible joint joint method.

The seventh gas passage moving member 17 may be connected to the sixth gas passage moving member 16. In addition, the seventh gas passage moving member 17 may be formed of a straight pipe.

The eighth gas passage moving member 18 may be connected to the seventh gas passage moving member 17. The eighth gas passage moving member 18 may be formed of an elbow-shaped pipe.

The ninth gas passage moving member 19 may be connected to the eighth gas passage moving member 18. In addition, the ninth gas passage moving member 19 is formed of a straight pipe, and can be connected to the discharge unit 60.

In addition, specifically, the second desulfurization gas moving part is a third gas passage intermediate crossing member 23, a 21 gas passage moving member 31, a 22 gas passage moving member 32, and a 23 gas passage moving member 33 , 24th gas channel moving member 34, 25th gas channel moving member 35, 26th gas channel moving member 36, 27th gas channel moving member 37, 28th gas channel moving member 38 , 29th gas passage moving member 39, a second body portion 80, a third activated carbon cartridge portion 130, a fourth activated carbon cartridge portion 140 and a fourth gas passage intermediate crossing member 24 Can.

The third gas passage intermediate crossing member 23 may be connected to the first gas passage intermediate crossing member 21. The third gas passage intermediate member 23 may be formed of a T-shaped pipe.

In addition, the third gas passage intermediate crossing member 23 may be formed in a structure that is separately connected to the input part 10. In this case, a separate valve may be formed between the third gas passage intermediate crossing member 23 and the input part 10.

The 21st gas passage moving member 31 may be connected to one side of the third gas passage intermediate diverging member 23. The 21st gas passage moving member 31 may be formed with a straight pipe.

The 22nd gas passage moving member 32 may be connected to the 21st gas passage moving member 31. In addition, the 22nd gas passage moving member 32 may be formed of elbow-shaped piping.

The 23rd gas passage moving member 33 may be connected to the 22nd gas passage 32 and the moving member. Further, the 23rd gas passage moving member 33 may be formed of a straight pipe.

The 24th gas passage moving member 34 may be connected to the 23rd gas passage moving member 33. In addition, the 24th gas passage moving member 34 may be formed of a flexible material. In addition, the 24th gas passage moving member 34 may be formed by a flexible joint joint method.

The 25th gas passage moving member 35 may be connected to the 24th gas passage moving member 34. In addition, the 25th gas passage moving member 35 may have a larger diameter at the other end than a diameter at one end. In addition, the diameter of the other end of the 25th gas passage moving member 35 may be formed to have the same diameter as the diameter of the second body portion 80.

The second body portion 80 may be connected to the other side of the 25th gas passage moving member 35. In addition, the second body portion 80 may be formed to have the same diameter as the diameter of the other end of the 25th gas passage moving member 35. In addition, the second body portion 80 may be formed long in the horizontal direction.

The third activated carbon cartridge unit 130 may be formed in a portion of the inner space of the second body unit 80 to serve to desulfurize the sulfur component of the biogas. In addition, the third activated carbon cartridge unit 130 may serve to adsorb and remove harmful substances in biogas. In addition, the third activated carbon cartridge unit 130 may accommodate a polling (not shown) serving as activated carbon therein.

The fourth activated carbon cartridge unit 140 may be formed on the other portion of the inner space of the second body portion 80 to serve to desulfurize the sulfur component of the biogas. In addition, the fourth activated carbon cartridge unit 140 may serve to adsorb and remove harmful substances in biogas. In addition, the fourth activated carbon cartridge unit 140 may accommodate a polling (not shown) serving as activated carbon therein. In addition, the fourth activated carbon cartridge unit 140 is preferably disposed in a step after the biogas passes through the third activated carbon cartridge unit 130.

The 26th gas passage moving member 36 may be connected to one side of the second body portion 80. In addition, the 26th gas passage moving member 36 may be formed to have a larger diameter at the other end than a diameter at one end, and a diameter at the other end having the same diameter as the diameter of the second body portion 80.

The 27th gas passage moving member 37 may be connected to the 26th gas passage moving member 36. In addition, the 27th gas passage moving member 37 may be formed of a flexible material. In addition, the 27th gas passage moving member 37 may be formed by a flexible joint joint method.

The 28th gas passage moving member 38 may be connected to the 27th gas passage moving member 37. In addition, the 28th gas passage moving member 38 may be formed of a straight pipe.

The 29th gas passage moving member 39 may be connected to the 28th gas passage moving member. Further, the 29th gas passage moving member 39 may be formed of an elbow-shaped pipe.

The fourth gas passage intermediate member 24 may be connected to the 29th gas passage moving member 39. In addition, the fourth gas passage intermediate member 24 is formed of a T-shaped pipe, and may be connected to the discharge unit 60.

The bypass passage part is a second gas passage intermediate crossing member 22, a tenth gas passage moving member 25, an eleventh gas passage moving member 26, a first valve part 51, and a second valve part 52 , A third valve part 53, a fourth valve part 54, a fifth valve part 55, a sixth valve part 56, and a seventh valve part 57.

Specifically, the second gas passage intermediate crossing member 22 is a ninth gas passage moving member 19 and a fourth gas passage intermediate crossing member so that the gas is moved to only one of the first desulfurization gas moving part and the second desulfurizing gas moving part It can be formed between (24). In addition, the second gas passage intermediate member 22 may be formed of a T-shaped pipe. In addition, the second gas passage intermediate crossing member 22 has a ninth gas passage moving member 19 and a fourth gas passage intermediate crossing member so that gas is moved to only one of the first desulfurization gas moving part and the second desulfurizing gas moving part ( 24).

The tenth gas passage moving member 25 may be connected to one side of the second gas passage intermediate crossing member 22. In addition, the tenth gas passage moving member 25 may be formed of a straight pipe.

The eleventh gas passage moving member 26 may be formed between the third gas passage intermediate member 23 and the tenth gas passage moving member 25. In addition, the eleventh gas passage moving member 26 may be formed of a straight pipe.

For reference, the bypass passage part may include a plurality of valve parts to serve to move the gas to only one of the first desulfurization gas moving part and the second desulfurizing gas moving part. Specifically, the bypass passage part includes a first valve part 51, a second valve part 52, a third valve part 53, a fourth valve part 54, a fifth valve part 55, and a sixth valve A portion 56 and a seventh valve portion 57 may be included.

The first valve part 51 may be formed between the first gas passage intermediate crossing member 21 and the first gas passage moving member 11. In addition, the first valve unit 51 may be configured using any one of a butterfly valve, a ball valve, an electric valve, a solenoid valve, and a check valve.

The second valve part 52 may be formed between the eighth gas passage moving member 18 and the ninth gas passage moving member 19. In addition, the second valve unit 52 may be configured using any one of a butterfly valve, a ball valve, an electric valve, a solenoid valve, and a check valve.

The third valve part 53 may be formed between the second gas passage intermediate crossing member 22 and the fourth gas passage intermediate crossing member 24. In addition, the third valve unit 53 may be configured using any one of a butterfly valve, a ball valve, an electric valve, a solenoid valve, and a check valve.

The fourth valve unit 54 may be formed between the tenth gas passage moving member 25 and the eleventh gas passage moving member 26. In addition, the fourth valve unit 54 may be configured using any one of a butterfly valve, a ball valve, an electric valve, a solenoid valve, and a check valve.

The fifth valve part 55 may be formed between the first gas passage intermediate crossing member 21 and the third gas passage intermediate crossing member 23. In addition, the fifth valve unit 55 may be configured using any one of a butterfly valve, a ball valve, an electric valve, a solenoid valve, and a check valve.

The sixth valve part 56 may be formed between the 21st gas passage moving member 31 and the 22nd gas passage moving member 32. In addition, the sixth valve unit 56 may be configured using any one of a butterfly valve, a ball valve, an electric valve, a solenoid valve, and a check valve.

The seventh valve portion 57 may be formed between the 29th gas passage moving member 39 and the 4th gas passage intermediate crossing member 24. In addition, the seventh valve portion 57 may be configured using any one of a butterfly valve, a ball valve, an electric valve, a solenoid valve, and a check valve.

In addition, the desulfurization device 1100 according to an embodiment of the present invention is formed on one side of the first activated carbon cartridge unit 110 is provided with a sensor capable of measuring the composition of the biogas at least one first sampling measurement unit ( Drawings (not shown).

In addition, the desulfurization device 1100 according to an embodiment of the present invention is formed on one side of the second activated carbon cartridge unit 120 is provided with a sensor capable of measuring the components of the biogas at least one second sampling measurement unit ( Drawings (not shown).

In addition, the desulfurization device 1100 according to an embodiment of the present invention is formed on one side of the third activated carbon cartridge 130, at least one third sampling measurement unit provided with a sensor capable of measuring the components of the biogas (Not shown) may further include.

In addition, the desulfurization device 1100 according to an embodiment of the present invention is formed on one side of the fourth activated carbon cartridge 140, at least one fourth sampling measurement unit is provided with a sensor capable of measuring the components of the biogas (Not shown) may further include.

3 and 7, the first activated carbon cartridge unit 110 will be described in detail.

The desulfurization device 1100 according to an embodiment of the present invention may include a first activated carbon cartridge unit 110.

The first activated carbon cartridge unit 110 includes a first cartridge frame unit 210, a first circular member 220, a mesh member 300, a through-hole 400, and a gas passage unit 500 inside the activated carbon cartridge. The gas passage member 510 inside the activated carbon cartridge, the gas passage member 520 inside the second activated carbon cartridge, the gas passage member 530 inside the third activated carbon cartridge, and the gas passage member 540 inside the fourth activated carbon cartridge may be included. .

Here, the gas passage 500 inside the activated carbon cartridge includes a gas passage member 510 inside the first activated carbon cartridge, a gas passage member 520 inside the second activated carbon cartridge, and a gas passage member 530 inside the third activated carbon cartridge. 4 may be formed in a structure including a gas passage member 540 inside the activated carbon cartridge.

In addition, the gas passage portion 500 inside the activated carbon cartridge may be configured as a gas passage member inside a plurality of activated carbon cartridges.

The first cartridge frame part 210 may be formed to have a long cylindrical shape.

The first circular member 220 may be formed inside the first cartridge frame part 210. In addition, the first circular member 220 may be at least one. Further, in the present invention, it may be formed in a structure using four first circular members 220.

The mesh member 300 may be formed to surround the outer diameter of the first cartridge frame portion 210. Also, the mesh member 300 may be at least one. For example, the mesh member 300 may be formed to wrap the first cartridge frame portion 210 in a layered structure with a plurality of layers. In addition, the mesh member 300 may be formed in a structure in which two or more layers of three or more layers are stacked.

The gas passage member 510 inside the first activated carbon cartridge may be provided on the first circular member 220 formed on one side of the first cartridge frame part 210. In addition, the gas passage member 510 inside the first activated carbon cartridge may change the movement path of the biogas by the through portion 400.

The gas passage member 520 inside the second activated carbon cartridge may be provided inside the first cartridge frame part 210. Further, the gas passage member 520 inside the second activated carbon cartridge may be formed after the gas passage member 510 inside the first activated carbon cartridge. In addition, the gas passage member 520 inside the second activated carbon cartridge may change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member inside the first activated carbon cartridge.

The gas passage member 530 inside the third activated carbon cartridge may be provided inside the first cartridge frame part 210. In addition, the gas passage member 530 inside the third activated carbon cartridge may be formed after the gas passage member 520 inside the second activated carbon cartridge. In addition, the gas passage member 530 inside the third activated carbon cartridge can change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member 520 inside the second activated carbon cartridge. .

The gas passage member 540 inside the fourth activated carbon cartridge may be provided inside the first cartridge frame part 210. In addition, the gas passage member 540 inside the fourth activated carbon cartridge may be formed after the gas passage member 530 inside the third activated carbon cartridge. In addition, the gas passage member 540 inside the fourth activated carbon cartridge may change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member 530 inside the third activated carbon cartridge. .

4 and 7, the second activated carbon cartridge unit 120 will be described in detail.

The desulfurization device 1100 according to an embodiment of the present invention may include a second activated carbon cartridge unit 120.

The second activated carbon cartridge unit 120 includes a first cartridge frame unit 210, a first circular member 220, a mesh member 300, a through hole 400, and a gas passage unit 500 inside the activated carbon cartridge. The gas passage member 510 inside the activated carbon cartridge, the gas passage member 520 inside the second activated carbon cartridge, the gas passage member 530 inside the third activated carbon cartridge, and the gas passage member 540 inside the fourth activated carbon cartridge may be included. .

Here, the gas passage 500 inside the activated carbon cartridge includes a gas passage member 510 inside the first activated carbon cartridge, a gas passage member 520 inside the second activated carbon cartridge, and a gas passage member 530 inside the third activated carbon cartridge. 4 may be formed in a structure including a gas passage member 540 inside the activated carbon cartridge.

In addition, the gas passage portion 500 inside the activated carbon cartridge may be configured as a gas passage member inside a plurality of activated carbon cartridges.

The first cartridge frame part 210 may be formed to have a long cylindrical shape.

The first circular member 220 may be formed inside the first cartridge frame part 210. In addition, the first circular member 220 may be at least one. Further, in the present invention, it may be formed in a structure using four first circular members 220.

The mesh member 300 may be formed to surround the outer diameter of the first cartridge frame part 210. Further, the mesh member 300 may be at least one. For example, the mesh member 300 may be formed to wrap the first cartridge frame portion 210 in a layered structure with a plurality of layers.

The gas passage member 510 inside the first activated carbon cartridge may be provided on the first circular member 220 formed on one side of the first cartridge frame part 210. In addition, the gas passage member 510 inside the first activated carbon cartridge may change the movement path of the biogas by the through portion 400.

The gas passage member 520 inside the second activated carbon cartridge may be provided inside the first cartridge frame part 210. Further, the gas passage member 520 inside the second activated carbon cartridge may be formed after the gas passage member 510 inside the first activated carbon cartridge. In addition, the gas passage member 520 inside the second activated carbon cartridge may change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member inside the first activated carbon cartridge.

The gas passage member 530 inside the third activated carbon cartridge may be provided inside the first cartridge frame part 210. In addition, the gas passage member 530 inside the third activated carbon cartridge may be formed after the gas passage member 520 inside the second activated carbon cartridge. In addition, the gas passage member 530 inside the third activated carbon cartridge can change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member 520 inside the second activated carbon cartridge. .

The gas passage member 540 inside the fourth activated carbon cartridge may be provided inside the first cartridge frame part 210. In addition, the gas passage member 540 inside the fourth activated carbon cartridge may be formed after the gas passage member 530 inside the third activated carbon cartridge. In addition, the gas passage member 540 inside the fourth activated carbon cartridge may change the movement path of biogas by the through part 400 differently from the through part 400 of the gas passage member 530 inside the third activated carbon cartridge. .

5 and 7, the third activated carbon cartridge unit 130 will be described in detail.

The desulfurization device 1100 according to an embodiment of the present invention may include a third activated carbon cartridge unit 130.

The third activated carbon cartridge unit 130 includes a first cartridge frame unit 210, a first circular member 220, a mesh member 300, a through-hole 400, and a gas passage unit 500 inside the activated carbon cartridge. The gas passage member 510 inside the activated carbon cartridge, the gas passage member 520 inside the second activated carbon cartridge, the gas passage member 530 inside the third activated carbon cartridge, and the gas passage member 540 inside the fourth activated carbon cartridge may be included. .

Here, the gas passage 500 inside the activated carbon cartridge includes a gas passage member 510 inside the first activated carbon cartridge, a gas passage member 520 inside the second activated carbon cartridge, and a gas passage member 530 inside the third activated carbon cartridge. 4 may be formed in a structure including a gas passage member 540 inside the activated carbon cartridge.

In addition, the gas passage portion 500 inside the activated carbon cartridge may be configured as a gas passage member inside a plurality of activated carbon cartridges.

The first cartridge frame part 210 may be formed to have a long cylindrical shape.

The first circular member 220 may be formed inside the first cartridge frame part 210. In addition, the first circular member 220 may be at least one. Further, in the present invention, it may be formed in a structure using four first circular members 220.

The mesh member 300 may be formed to surround the outer diameter of the first cartridge frame part 210. Further, the mesh member 300 may be at least one. For example, the mesh member 300 may be formed to wrap the first cartridge frame portion 210 in a layered structure with a plurality of layers.

The gas passage member 510 inside the first activated carbon cartridge may be provided on the first circular member 220 formed on one side of the first cartridge frame part 210. In addition, the gas passage member 510 inside the first activated carbon cartridge may change the movement path of the biogas by the through portion 400.

The gas passage member 520 inside the second activated carbon cartridge may be provided inside the first cartridge frame part 210. Further, the gas passage member 520 inside the second activated carbon cartridge may be formed after the gas passage member 510 inside the first activated carbon cartridge. In addition, the gas passage member 520 inside the second activated carbon cartridge may change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member inside the first activated carbon cartridge.

The gas passage member 530 inside the third activated carbon cartridge may be provided inside the first cartridge frame part 210. In addition, the gas passage member 530 inside the third activated carbon cartridge may be formed after the gas passage member 520 inside the second activated carbon cartridge. In addition, the gas passage member 530 inside the third activated carbon cartridge can change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member 520 inside the second activated carbon cartridge. .

The gas passage member 540 inside the fourth activated carbon cartridge may be provided inside the first cartridge frame part 210. In addition, the gas passage member 540 inside the fourth activated carbon cartridge may be formed after the gas passage member 530 inside the third activated carbon cartridge. In addition, the gas passage member 540 inside the fourth activated carbon cartridge may change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member 530 inside the third activated carbon cartridge. .

6 and 7, the fourth activated carbon cartridge unit 140 will be described in detail.

The desulfurization device 1100 according to an embodiment of the present invention may include a fourth activated carbon cartridge unit 140.

The fourth activated carbon cartridge unit 140 includes a first cartridge frame unit 210, a first circular member 220, a mesh member 300, a through-hole 400, and a gas passage unit 500 inside the activated carbon cartridge. The gas passage member 510 inside the activated carbon cartridge, the gas passage member 520 inside the second activated carbon cartridge, the gas passage member 530 inside the third activated carbon cartridge, and the gas passage member 540 inside the fourth activated carbon cartridge may be included. .

Here, the gas passage 500 inside the activated carbon cartridge includes a gas passage member 510 inside the first activated carbon cartridge, a gas passage member 520 inside the second activated carbon cartridge, and a gas passage member 530 inside the third activated carbon cartridge. 4 may be formed in a structure including a gas passage member 540 inside the activated carbon cartridge.

In addition, the gas passage portion 500 inside the activated carbon cartridge may be configured as a gas passage member inside a plurality of activated carbon cartridges.

The first cartridge frame part 210 may be formed to have a long cylindrical shape.

The first circular member 220 may be formed inside the first cartridge frame part 210. In addition, the first circular member 220 may be at least one. Further, in the present invention, it may be formed in a structure using four first circular members 220.

The mesh member 300 may be formed to surround the outer diameter of the first cartridge frame part 210. Further, the mesh member 300 may be at least one. For example, the mesh member 300 may be formed to wrap the first cartridge frame portion 210 in a layered structure with a plurality of layers.

The gas passage member 510 inside the first activated carbon cartridge may be provided on the first circular member 220 formed on one side of the first cartridge frame part 210. In addition, the gas passage member 510 inside the first activated carbon cartridge may change the movement path of the biogas by the through portion 400.

The gas passage member 520 inside the second activated carbon cartridge may be provided inside the first cartridge frame part 210. Further, the gas passage member 520 inside the second activated carbon cartridge may be formed after the gas passage member 510 inside the first activated carbon cartridge. In addition, the gas passage member 520 inside the second activated carbon cartridge may change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member inside the first activated carbon cartridge.

The gas passage member 530 inside the third activated carbon cartridge may be provided inside the first cartridge frame part 210. In addition, the gas passage member 530 inside the third activated carbon cartridge may be formed after the gas passage member 520 inside the second activated carbon cartridge. In addition, the gas passage member 530 inside the third activated carbon cartridge can change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member 520 inside the second activated carbon cartridge. .

The gas passage member 540 inside the fourth activated carbon cartridge may be provided inside the first cartridge frame part 210. In addition, the gas passage member 540 inside the fourth activated carbon cartridge may be formed after the gas passage member 530 inside the third activated carbon cartridge. In addition, the gas passage member 540 inside the fourth activated carbon cartridge may change the movement path of the biogas by the through part 400 differently from the through part 400 of the gas passage member 530 inside the third activated carbon cartridge. .

In addition, the desulfurization device 1100 may further include a control unit (not shown).

Also, the control unit and at least one sensor unit in the apparatus may be wirelessly connected. For reference, the sensor unit may include a first sampling measurement unit, a second sampling measurement unit, a third sampling measurement unit, and a fourth sampling measurement unit.

In addition, information on the components of the biogas measured by the sensor unit (not shown) may be transmitted to the control unit using wired communication or wireless communication. In addition, the sensor unit may include a wireless communication module. A plurality of sensor units may be formed.

In addition, the user can check the measured value in real time by using the smart device for information on the composition of the biogas delivered to the control unit.

Accordingly, the operator can grasp in real time the components of the biogas flowing into the generator from the discharge unit 60, thereby providing an advantage of quickly responding to an error.

In addition, the desulfurization apparatus 1100 according to an embodiment of the present invention also controls on/off, flow rate, and inflow rate of biogas (G) input to the input unit 10 by a blower (not shown). A control unit (not shown) may be further included.

In addition, the control unit may control the amount of air injected into the blower by receiving the fluid movement speed of the biogas measured by the sensor unit so that the biogas G discharges a certain amount to the discharge unit 60.

In addition, a discharge unit opening/closing door member (not shown) for opening and closing the discharge unit 60 to supply or block the biogas supplied to the combustion chamber of the boiler or the generator through the discharge unit 60 may be further included.

The discharge opening/closing door member may be configured as a sliding door type in which a power transmission unit is connected to one side. In addition, the discharge opening and closing door member may be connected to the control unit.

For reference, each member or parts may be welded to form a system for a biogas cogeneration generator according to an embodiment of the present invention. In this case, a welding method such as gas welding, tarbit welding, arc welding, oxygen welding, and electric welding may be used.

In addition, each member or parts of the present invention can be coupled to each other using a fastening method using a flange, nut and bolt.

In particular, since the system for a biogas cogeneration system, which is a device used in the field of a biogas plant such as the present invention, is exposed in a corrosive environment, it is recommended to use STS 304 or STS 316 or higher material to prevent corrosion good.

In addition, the system for a biogas cogeneration generator may include a control unit (not shown).

In addition, information on the components of the biogas measured by the first methane gas measurement unit 710 or the second methane gas measurement unit 720 may be transmitted to the control unit using wired communication or wireless communication.

In addition, the user can check the measured value in real time by using the smart device for information on the composition of the biogas delivered to the control unit.

Accordingly, an operator can grasp the components of the biogas flowing into the cogeneration generator 900 in real time, thereby providing an advantage of quickly responding to an abnormality.

The present invention described above is not limited by the above-described embodiments, and various substitutions, modifications, and changes are possible without departing from the technical spirit of the present invention. It will be obvious to you.

In addition, since the components shown in the drawings may be displayed by being enlarged or reduced for convenience of description, the present invention is not limited to the size or shape of the components shown in the drawings, and general knowledge in the art Those of skill in the art will appreciate that various modifications and other equivalent embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1: Biogas cogeneration system
10: input section
11: First gas passage moving member
12: second gas passage moving member
13: third gas passage moving member
14: fourth gas passage moving member
15: fifth gas passage moving member
16: 6th gas passage moving member
17: 7th gas passage moving member
18: 8th gas passage moving member
19: 9th gas passage moving member
21: first gas passage intermediate fork member
22: second gas passage intermediate crossing member
23: 3rd gas passage intermediate crossing member
24: 4th gas passage intermediate crossing member
25: 10th gas passage moving member
26: 11th gas passage moving member
31: 21st gas passage moving member
32: 22nd gas passage moving member
33: 23rd gas passage moving member
34: 24th gas passage moving member
35: 25th gas passage moving member
36: 26th gas passage moving member
37: 27th gas passage moving member
38: 28th gas passage moving member
39: 29th gas passage moving member
51: first valve unit
52: second valve unit
53: third valve unit
54: fourth valve unit
55: fifth valve unit
56: 6th valve unit
57: seventh valve portion
60: outlet
70: first body portion
80: second body portion
110: first activated carbon cartridge unit
120: second activated carbon cartridge unit
130: third activated carbon cartridge unit
140: fourth activated carbon cartridge unit
210: first cartridge frame unit
220: first circular member
300: mesh member
400: Ministry of Transportation
500: gas passage inside the activated carbon cartridge
510: gas passage member inside the first activated carbon cartridge
520: gas passage member inside the second activated carbon cartridge
530: Gas passage member inside the third activated carbon cartridge
540: gas passage member inside the fourth activated carbon cartridge
600: gas street part
700: gas mixer
710: first methane gas measurement unit
720: second methane gas measurement unit
800: air inlet
810: air filter unit
900: Cogeneration Generator
1000: Korea Electric Power Corporation
1100: desulfurization device
G: Biogas

Claims (8)

A gas treatment unit pre-processing the biogas inputted through the biogas supply pipe;
A gas mixer unit mixing biogas and air pre-treated and supplied from the gas street unit;
A cogeneration generator in which biogas and air are mixed in the gas mixer unit and mixed gas is introduced;
A first methane gas measuring unit which is formed between the gas stream unit and the gas mixer unit and detects the concentration of methane gas (CH ₄ ) in the biogas that is moved from the gas street unit to the gas mixer unit;
A second methane gas measurement unit which is formed between the gas mixer unit and the cogeneration generator and detects the concentration of methane gas (CH ₄ ) in the biogas transferred from the gas mixer unit to the cogeneration generator;
It is connected to the gas mixer unit, the air input unit for introducing air into the gas mixer unit;
An air filter unit formed between the air input unit and the gas mixer unit, and performing a role of removing fine dust or dust from the air input from the air input unit; And
Includes; desulfurization device formed between the second methane gas measurement unit and the cogeneration generator,
The control unit receives information on the concentration of methane gas (CH ₄ ) measured by the first methane gas measurement unit and the second methane gas measurement unit,
The control unit,
The gas mixer unit is controlled so that the concentration of methane gas (CH ₄ ) in the biogas inputted to the cogeneration generator is supplied at a set concentration of methane gas (CH ₄ ), and the preset methane gas (CH ₄ ) in the gas mixer unit. Control the air to mix,
The first methane gas measuring unit measures the concentration of methane gas (CH ₄ ) supplied from the gas processing unit to the gas mixer unit using a methane gas concentration meter installed on one side, and transmits a signal to the control unit,
The second methane gas measurement unit measures the concentration of methane gas (CH ₄ ) supplied from the gas mixer unit to the cogeneration generator using a methane gas concentration meter installed on one side, and transmits a signal to the control unit,
The desulfurization device,
Adsorption and removal of harmful substances in biogas using activated carbon Cartridge exchange type dry desulfurization device,
An input part into which biogas flows;
An outlet connected to the generator so that the biogas introduced into the inlet is discharged to the generator;
A first desulfurization gas moving part which is connected to the input part and the discharge part and reduces sulfur of the biogas and moves it to the discharge part;
A second desulfurization gas moving part which is connected to the input part and the discharge part and reduces sulfur of the biogas and moves it to the discharge part; And
It includes; Bypass passage unit for controlling the gas to be moved to only one of the first desulfurization gas moving unit and the second desulfurization gas moving unit;
The first desulfurization gas mobile unit,
A first gas passage intermediate crossing member connected to one side of the discharge part and formed of a T-shaped pipe;
A first gas passage moving member connected to one side of the first gas passage intermediate crossing member and formed of an elbow-shaped pipe;
A second gas passage moving member connected to the first gas passage moving member and formed of a straight pipe;
A third gas passage moving member connected to the second gas passage moving member and formed of a flexible material;
A fourth gas passage moving member connected to the third gas passage moving member and having a larger diameter at the other end than a diameter at one end;
A first body part connected to the other side of the fourth gas passage moving member and formed to have the same diameter as the diameter of the other end of the fourth gas passage moving member;
A first activated carbon cartridge unit formed in a part of the inner space of the first body unit to desulfurize the sulfur component of the biogas;
A second activated carbon cartridge unit formed on another portion of the inner space of the first body portion to desulfurize the sulfur component of the biogas;
A fifth gas passage moving member connected to one side of the first body portion, the diameter of the other end being larger than that of one end, and the diameter of the other end having the same diameter as the diameter of the first body portion;
A sixth gas passage moving member connected to the fifth gas passage moving member and formed of a flexible material;
A seventh gas passage moving member connected to the sixth gas passage moving member and formed of a straight pipe;
An eighth gas passage moving member connected to the seventh gas passage moving member and formed of an elbow-shaped pipe;
It includes; a ninth gas passage moving member connected to the eighth gas passage moving member, formed of a straight pipe, and connected to the discharge part;
The second desulfurization gas moving unit,
A third gas passage intermediate crossing member connected to the first gas passage intermediate crossing member and formed of a T-shaped pipe;
A 21st gas passage moving member connected to one side of the third gas passage intermediate crossing member and formed of a straight pipe;
A twenty-first gas passage moving member connected to the twenty-first gas passage moving member and formed of an elbow-shaped pipe;
A 23rd gas passage moving member connected to the 22nd gas passage moving member and formed of a straight pipe;
A 24th gas passage moving member connected to the 23rd gas passage moving member and formed of a flexible material;
A 25th gas passage moving member connected to the 24th gas passage moving member and having a larger diameter at the other end than a diameter at one end;
A second body part connected to the other side of the 25th gas passage moving member and formed to have the same diameter as the diameter of the other end of the 25th gas passage moving member;
A third activated carbon cartridge unit formed in a part of the inner space of the second body unit to desulfurize the sulfur component of the biogas;
A fourth activated carbon cartridge unit formed on another portion of the inner space of the second body portion to desulfurize the sulfur component of the biogas;
A 26th gas passage moving member connected to one side of the second body part, the diameter of the other end being larger than that of one end, and the diameter of the other end being formed to have the same diameter as the diameter of the second body part;
A 27th gas passage moving member connected to the 26th gas passage moving member and formed of a flexible material;
A 28th gas passage moving member connected to the 27th gas passage moving member and formed of a straight pipe;
A 29th gas passage moving member connected to the 28th gas passage moving member and formed of an elbow-shaped pipe; And
It includes; a fourth gas passage intermediate crossing member connected to the 29th gas passage moving member, formed of a T-shaped pipe, and connected to the discharge part;
The bypass passage part,
It is formed between the ninth gas passage moving member and the fourth gas passage intermediate crossing member so that gas is moved to only one of the first desulfurization gas moving part and the second desulfurizing gas moving part, and is formed by a T-shaped pipe. 2 gas passage intermediate crossing member;
A tenth gas passage moving member connected to one side of the second gas passage intermediate crossing member and formed of a straight pipe; And
It is formed between the third gas passage intermediate crossing member and the tenth gas passage moving member, the eleventh gas passage moving member formed of a straight pipe;
The bypass passage unit serves to move the gas to only one of the first desulfurization gas moving unit and the second desulfurization gas moving unit.
A first valve portion formed between the first gas passage intermediate crossing member and the first gas passage moving member;
A second valve part formed between the eighth gas passage moving member and the ninth gas passage moving member;
A third valve part formed between the second gas passage intermediate crossing member and the fourth gas passage intermediate crossing member;
A fourth valve part formed between the tenth gas passage moving member and the eleventh gas passage moving member;
A fifth valve portion formed between the first gas passage intermediate crossing member and the third gas passage intermediate crossing member;
A sixth valve portion formed between the 21st gas passage moving member and the 22nd gas passage moving member;
And a seventh valve portion formed between the 29th gas passage moving member and the 4th gas passage intermediate crossing member.
delete delete delete According to claim 1,
The first activated carbon cartridge unit,
A first cartridge frame portion formed in a cylindrical shape;
At least one first circular member formed inside the first cartridge frame portion;
At least one mesh member formed to surround the outer diameter of the first cartridge frame portion;
A gas passage member inside the first activated carbon cartridge which is provided on the first circular member formed on one side of the first cartridge frame part and changes the movement path of the biogas by the through hole;
It is provided inside the first cartridge frame portion, is formed after the gas passage member inside the first activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the first activated carbon cartridge. A gas passage member inside the second activated carbon cartridge to change;
It is provided inside the first cartridge frame portion, is formed next to the gas passage member inside the second activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the second activated carbon cartridge. A gas passage member inside the third activated carbon cartridge for changing; And
It is provided inside the first cartridge frame portion, and is formed after the gas passage member inside the third activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the third activated carbon cartridge. A system for a biogas cogeneration system comprising a gas passage member inside a fourth activated carbon cartridge to change.
According to claim 1,
The second activated carbon cartridge unit,
A first cartridge frame portion formed in a cylindrical shape;
At least one first circular member formed inside the first cartridge frame portion;
At least one mesh member formed to surround the outer diameter of the first cartridge frame portion;
A gas passage member inside the first activated carbon cartridge which is provided on the first circular member formed on one side of the first cartridge frame part and changes the movement path of the biogas by the through hole;
It is provided inside the first cartridge frame portion, is formed after the gas passage member inside the first activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the first activated carbon cartridge. A gas passage member inside the second activated carbon cartridge to change;
It is provided inside the first cartridge frame portion, is formed next to the gas passage member inside the second activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the second activated carbon cartridge. A gas passage member inside the third activated carbon cartridge for changing; And
It is provided inside the first cartridge frame portion, and is formed after the gas passage member inside the third activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the third activated carbon cartridge. A system for a biogas cogeneration system comprising a gas passage member inside a fourth activated carbon cartridge to change.
According to claim 1,
The third activated carbon cartridge unit,
A first cartridge frame portion formed in a cylindrical shape;
At least one first circular member formed inside the first cartridge frame portion;
At least one mesh member formed to surround the outer diameter of the first cartridge frame portion;
A gas passage member inside the first activated carbon cartridge which is provided on the first circular member formed on one side of the first cartridge frame part and changes the movement path of the biogas by the through hole;
It is provided inside the first cartridge frame portion, is formed after the gas passage member inside the first activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the first activated carbon cartridge. A gas passage member inside the second activated carbon cartridge to change;
It is provided inside the first cartridge frame portion, is formed next to the gas passage member inside the second activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the second activated carbon cartridge. A gas passage member inside the third activated carbon cartridge for changing; And
It is provided inside the first cartridge frame portion, and is formed after the gas passage member inside the third activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the third activated carbon cartridge. A system for a biogas cogeneration system comprising a gas passage member inside a fourth activated carbon cartridge to change.
According to claim 1,
The fourth activated carbon cartridge unit,
A first cartridge frame portion formed in a cylindrical shape;
At least one first circular member formed inside the first cartridge frame portion;
At least one mesh member formed to surround the outer diameter of the first cartridge frame portion;
A gas passage member inside the first activated carbon cartridge which is provided on the first circular member formed on one side of the first cartridge frame part and changes the movement path of the biogas by the through hole;
It is provided inside the first cartridge frame portion, is formed after the gas passage member inside the first activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the first activated carbon cartridge. A gas passage member inside the second activated carbon cartridge to change;
It is provided inside the first cartridge frame portion, is formed next to the gas passage member inside the second activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the second activated carbon cartridge. A gas passage member inside the third activated carbon cartridge for changing; And
It is provided inside the first cartridge frame portion, and is formed after the gas passage member inside the third activated carbon cartridge, and the movement path of the biogas by the through hole is different from that of the gas passage member inside the third activated carbon cartridge. A system for a biogas cogeneration system comprising a gas passage member inside a fourth activated carbon cartridge to change.

Images