CN204676043U - The device of preparing synthesis gas from coke-oven gas - Google Patents

Abstract

The utility model discloses the device of preparing synthesis gas from coke-oven gas, this device comprises: humidity control system (M1), one section of adiabatic reactor (R1), first condensation water diversion system (M2), two sections of internal heat exchange type methanators (R2), second condensation water diversion system (M3), and recycle compressor (C1).

Description

The device of preparing synthesis gas from coke-oven gas

Technical field

The utility model relates to synthetic natural gas field, particularly a kind of device from preparing synthesis gas from coke-oven gas.

Background technology

China is the main grown place of world's coke, and the coke output in 2013 reaches 4.76 hundred million tons.Often produce one ton of coke energy by-product 400Nm ³coke(oven)gas.Removing heating is used by oneself and for outside town gas, production synthetic ammonia or methyl alcohol, is had a large amount of coke(oven)gas to be taken as waste gas every year and directly enter air or burn in vain, not only cause energy dissipation, also can bring serious environmental pollution.

Sweet natural gas is considered to a kind of clean, convenient, safe high-grade energy, and its main component is methane (CH ₄) be widely used in the industries such as generating, chemical industry, gas, be one of main in the world clean energy.But China's natural gas scarcity of resources, gas production far can not meet the demand of consumption, causes the import of Sweet natural gas significantly to increase year by year.Therefore, people start concern and utilize coke(oven)gas to produce Sweet natural gas, thus make up the increased requirement of Sweet natural gas.

Disclosing a kind of coke(oven)gas in patent CN101580748A is unstripped gas, through the method for methanation reaction preparing natural gas, it is characterized in that adopting the outer cold heat exchange type reactor process of single hop to carry out the methane building-up process of coke(oven)gas.Due to the strong exothermal reaction that methanation reaction is a high reaction rate, external-cooling type methanator described in this technique runs not quietly, there is potential safety hazard.When after synthesizing, gas is for the production of natural gas liquids, single hop reactor effectively can not prevent the fluctuation of feed gas composition, causes rear workshop section to occur CO ₂frozen block problem.

Disclose a kind of technique of preparing synthesis gas from coke-oven gas in patent CN102329670A, it adopts three sections of reactor process, one or two sections of series-parallel connection, and three sections of reactors adopt isothermal or adiabatic reactor.This technique is comparatively complicated, and facility investment is large; Second stage exit gas needs cooling water dividing, and then enters three sections of reactors after heating, and this process is that system introduces malaria, adds system energy consumption.

Utility model content

For the problems referred to above, the utility model provides a kind of succinct technique of preparing synthesis gas from coke-oven gas.

The designer of the utility model people finds unexpectedly, by adopting second stage reactor to connect in coke(oven)gas synthetic natural gas process, wherein, one section adopts adiabatic reactor (heat-insulating methanator), two sections adopt internal heat exchange type reactor (internal heat exchange type methanator), enter first stage reactor after coke(oven)gas after compression purification mixes with circulation gas and carry out methanation reaction, after reaction, gas is through heat recuperation, two portions are divided into after cooling, a part mixes with unstripped gas after recycle compressor compression as circulation gas, another part directly enters second stage reactor and proceeds methanation reaction, can avoidance system malaria effectively, reduce system energy consumption, greatly improve the economic benefit of device, effectively synthetic natural gas can be prepared with simple system.This completes the utility model.

Specifically, the utility model provides a kind of succinct technique of preparing synthesis gas from coke-oven gas, and this technique comprises the steps:

(A) coke(oven)gas after the coke(oven)gas or compression purification of unstripped gas is mixed with the circulation gas from recycle compressor, be adjusted to 230-350 DEG C by humidity control system, preferred 250-320 DEG C;

(B) adiabatic reactor regulating the gas mixture after temperature to enter a section carries out methanation reaction;

(C) after the reaction that obtains of above step (B), gas carries out condensation and divides water (preferably, also have energy recovery) and obtain the gas mixture dewatered, then this gas mixture is divided into two portions, wherein first part gas mixture as circulation gas after recycle compressor compression with as unstripped gas coke(oven)gas or compress the coke(oven)gas after purifying and mix, the gas mixture of second section is directly delivered in the internal heat exchange type reactor of two sections;

(D) gas mixture entered in the internal heat exchange type reactor of two sections proceeds methanation reaction and obtains high methane gas; With

(E) high methane gas of gained after methanation reaction in step (D) is carried out condensation and divide water (preferably, also having energy recovery), obtain synthetic natural gas.

Preferably, in step (A), be 0.5 ~ 1.5:1 as the coke(oven)gas after the coke(oven)gas of unstripped gas or compression purification with the mol ratio (or when both equipressures by volume) from the circulation gas of recycle compressor, preferably 0.6 ~ 1.4:1, more preferably 0.7 ~ 1.4:1.

Preferably, in step (C), the mol ratio that the gas mixture of first part accounts for whole gas mixture (i.e. first part+second section) is 30 ~ 85%, preferably 40 ~ 80%, the mol ratio that second section gas accounts for all gas is 15 ~ 70%, preferably 20 ~ 60%.

In the methanation reaction of step (B), the temperature in of the adiabatic reactor of described a section is 230 ~ 350 DEG C, preferably 250 DEG C ~ 320 DEG C, more preferably 260 DEG C ~ 310 DEG C.Inner bed hot(test)-spot temperature is 530 ~ 650 DEG C, preferably 545 DEG C ~ 620 DEG C, more preferably 560 DEG C ~ and 600 DEG C.

Preferably, in the methanation reaction of step (D), the temperature in (or temperature in of recycle compressor) of the internal heat exchange type reactor of described two sections is 95 DEG C ~ 320 DEG C, is preferably 100 DEG C ~ 305 DEG C, is more preferably 120 DEG C ~ 290 DEG C.The inside bed inlet temperatures of second stage reactor is 230 DEG C ~ 350 DEG C, be preferably 250 DEG C ~ 320 DEG C, more preferably 260 DEG C ~ 310 DEG C.The bed hot(test)-spot temperature of second stage reactor is 250 DEG C ~ 450 DEG C, preferably 265 DEG C ~ 430 DEG C, more preferably 270 ~ 420 DEG C.

Preferably, in the methanation reaction of step (B) and/or (D), conventional methanation catalyst is used.Preferably, described methanation catalyst comprises the Al of 50-60 quality % ₂o ₃, 20-30 quality % MgO, 20-30 quality % NiO composition or be made up of them.

In general, the adiabatic reactor of a section and the internal heat exchange type reactor air speed separately of two sections are 3000h independently ^-1~ 30000h ^-1, more preferably 4000h ^-1~ 25000h ^-1, more preferably 5000h ^-1~ 20000h ^-1.

Generally, as the total sulfur content≤100ppb (v/v) of the coke(oven)gas after the compression purification of unstripped gas.Its pressure maintains 1.5MPaG ~ 3.5MPaG usually, preferably at 1.3MPaG ~ 3.2MPaG, more preferably at 1.5MPaG ~ 3.5MPaG.

Usually, the composition of unstripped gas, by volume % meter, for: H ₂: 56.0-68.0 volume %, CO:6.0-12.0 volume %, CO ₂: 1.0-5.0 volume %, CH ₄: 18.0-27.0 volume %, N ₂: 2.0-6.0 volume %, H ₂o:0.8-2.0 volume %, C _nh _m: 1.5-3.0 volume %, O ₂: and 0-1.0 volume %, wherein n is 2-6, m is 4-15.

Generally, the CH of synthetic natural gas that obtains of step (E) ₄purity reaches more than 69.6vol%, and not containing CO, CO ₂and C _nh _m, wherein n is 2-6, m is 4-15.

Adiabatic methanation reactor described in the utility model refers to: with the heat-insulating fixed bed methanator of inner insulated lining.Internal heat exchange type methanator described in the utility model refers to: at inside reactor, and unstripped gas, by carrying out heat exchange with beds gas, enters the methanator that beds carries out methanation reaction after being preheated.

Methane synthesis reactor disclosed in Chinese patent 200910084411.2 can be adopted for the internal heat exchange type methanator in the utility model.This internal heat exchange type methanation synthesis reactor comprises reactor shell, case top is provided with raw material inlet mouth and quench gas inlet mouth, housing bottom is provided with product air outlet, housing upper has top deck, bottom has bottom deck, reactor head sealing is formed with top cushion chamber with top deck, catalyzer bottom deck and reactor bottom seal and form lower buffer chamber, quench gas sparger is provided with below top deck, upper packing layers is provided with below quench gas sparger, what below catalyzer bottom deck, arrange upstream and downdraft is communicated with air cavity, bottom packing layer is provided with on catalyzer bottom deck, between upper packing layer and lower packing layer, beds is being set, in beds, thermopair is set, be provided with countercurrent flow pipe and following current heat transfer tube in addition, the top of following current heat transfer tube is arranged in reactor head and seals the cushion chamber formed with top deck, the top of countercurrent flow pipe is on top deck and catalyzer between packing layer, the bottom of following current heat transfer tube and countercurrent flow pipe is arranged in the bottom deck of catalyzer and reactor bottom seals the cushion chamber formed, and for ensureing the unobstructed and heat exchange efficiency of air-flow, the bottom of preferred countercurrent flow pipe is lower than the bottom of following current heat transfer tube.

According to another aspect of the present utility model, provide a kind of device from preparing synthesis gas from coke-oven gas, this device comprises humidity control system, one section of adiabatic reactor, first condensation water diversion system, two sections of internal heat exchange type methanators, second condensation water diversion system and recycle compressor, wherein, coke(oven)gas feeding line is connected to one section of adiabatic reactor entrance via humidity control system, one section of adiabatic reactor outlet is connected to the entrance of the first condensation water diversion system, first condensation water diversion system outlet is divided into two branch roads, first branch road converges via recycle compressor and coke(oven)gas feeding line, second branch road is connected to two sections of internal heat exchange type reactor inlets, two sections of internal heat exchange type reactor outlets are connected to the second condensation water diversion system entrance, second condensation water diversion system outlet is connected with synthetic natural gas line of pipes.

More particularly, provide a kind of for the device from preparing synthesis gas from coke-oven gas in above-described technique, this device comprises:

Humidity control system, the inlet mouth of this system is connected with coke(oven)gas transfer lime (or coke(oven)gas feeding line);

The adiabatic reactor of one section, the inlet mouth of this reactor is connected to the air outlet of humidity control system via second pipe;

First condensation water diversion system, the inlet mouth of this water diversion system is connected to the air outlet of reactor via the 3rd pipeline;

The internal heat exchange type methanator of two sections, the inlet mouth of this reactor is connected to the air outlet of water diversion system via the 4th pipeline;

Second condensation water diversion system, the inlet mouth of this water diversion system is connected to the air outlet of reactor and the air outlet of this water diversion system via the 5th pipeline and is connected with the transport pipe of synthetic natural gas; With

Recycle compressor, wherein separate a branch road i.e. the 6th pipeline from the 4th pipeline (connecting tube namely between water diversion system and reactor) and be connected to the inlet mouth of recycle compressor, and the air outlet of recycle compressor is connected to coke(oven)gas transfer lime (or coke(oven)gas feeding line) via the 7th pipeline.

Compared with prior art, excellent effect of the present utility model is: coke(oven)gas synthetic natural gas process adopts two reactor, and technique is simple, reduces facility investment, and second stage reactor can effectively contend with, coke(oven)gas component fluctuation is to CO in synthesis gas product ₂impact, ensure the normal operation of follow-up workshop section.Two sections adopt internal heat exchange type reactor, one section outlet gas can be made directly to enter two sections of anti-devices, evaded system malaria, decreased system energy consumption, greatly improved the economic benefit of device.

Accompanying drawing explanation

Figure 1 shows that the device schematic diagram of comparative example 1.

In FIG:

M1 first stage reactor temperature in regulation system

R1 mono-section of adiabatic reactor

M2 first condensation water diversion system

R2 ' two sections of adiabatic reactors

M3 second condensation water diversion system (product cooling water dividing system)

C1 recycle compressor

M4 second stage reactor temperature in regulation system

Figure 2 shows that the utility model device schematic diagram.

In fig. 2:

M1 humidity control system

R1 mono-section of adiabatic reactor

M2 first condensation water diversion system

R2 bis-sections of internal heat exchange type reactors

M3 second condensation water diversion system

C1 recycle compressor

L1: the first pipeline (coke(oven)gas line of pipes or feeding line)

L2: the second pipeline

L3: the three pipeline

L4: the four pipeline

L5: the five pipeline

L6: the six pipeline

L7: the seven pipeline

L8: the eight pipeline (synthetic natural gas line of pipes)

Figure 3 shows that internal heat exchange type structure of reactor schematic diagram.

In figure 3:

1-unstripped gas; 2-decline gas; 3-ascending gas; 4-unstripped gas; 5-reaction gas; 6,7-gas product; 8-quench gas; 9-raw material inlet mouth; 10-quench gas inlet mouth; 11-housing; 12-top cushion chamber; 13-top deck; 14-quench gas sparger; 15-packing layer; 16-beds; 17-countercurrent flow pipe; 18-following current heat transfer tube; 19-bottom deck; 20-is communicated with air cavity; 21-lower buffer chamber; 22-product air outlet; 23-thermopair.

Embodiment

Mode below by embodiment is further described the utility model, should be appreciated that to be only preferred embodiment of the present utility model below, can not limit scope of the present utility model with this.I.e. every change of doing according to the utility model claim and modification, all includes in scope that the utility model patent contains.

Fig. 2 shows device layout diagram of the present utility model, first pipeline (coke(oven)gas line of pipes) L1 connects humidity control system M1 entrance, humidity control system M1 outlet is connected to one section of adiabatic reactor R1 entrance via the second pipeline L2, one section of adiabatic reactor R1 outlet is connected to the first condensation water diversion system M2 entrance by the 3rd pipeline L3, first condensation water diversion system M2 outlet is divided into two arms i.e. the 4th pipeline L4 and the 6th pipeline L6, 4th pipeline L4 is connected to two sections of internal heat exchange type reactor R2 entrances, two sections of internal heat exchange type reactor R2 outlets are connected to the second condensation water diversion system M3 entrance via the 5th pipeline L5, second condensation water diversion system M3 outlet is connected with the 8th pipeline L8 (synthetic natural gas line of pipes), 6th pipeline L6 is connected to recycle compressor C1 entrance, recycle compressor C1 outlet converges via the 7th pipeline L7 and the first pipeline (coke(oven)gas line of pipes or coke(oven)gas feeding line) L1.

Two sections of internal heat exchange type reactors use the reactor shown in Fig. 3 in an embodiment, wherein, this reactor comprises reactor shell 11, case top is provided with raw material inlet mouth 9 and quench gas inlet mouth 10, housing bottom is provided with product air outlet 22, housing upper has top deck 13, bottom has bottom deck 19, reactor head sealing is formed with top cushion chamber 12 with top deck, catalyzer bottom deck and reactor bottom seal and form lower buffer chamber 21, quench gas sparger 14 is provided with below top deck, upper packing layers 15 is provided with below quench gas sparger 14, what below catalyzer bottom deck, arrange upstream and downdraft is communicated with air cavity 20, bottom packing layer 15 is provided with on catalyzer bottom deck 19, between upper packing layer and lower packing layer 15, beds 16 is being set, thermopair 23 is set in beds 16, be provided with countercurrent flow pipe 17 and following current heat transfer tube 18 in addition, the top of following current heat transfer tube is arranged in reactor head and seals the cushion chamber formed with top deck, the top of countercurrent flow pipe is on top deck and catalyzer between packing layer, the bottom of following current heat transfer tube 18 and countercurrent flow pipe 17 is arranged in the bottom deck of catalyzer and reactor bottom seals the cushion chamber formed, and for ensureing the unobstructed and heat exchange efficiency of air-flow, the bottom of preferred countercurrent flow pipe is lower than the bottom of following current heat transfer tube.Quench gas inlet mouth 10 is directly communicated to quench gas sparger 14, quench gas sparger 14 is distributed with the quench gas sparger air outlet (small sircle hole) of many (being usually uniformly distributed).

Unstripped gas 1 enters reactor head from case top raw material inlet mouth 9 and seals the cushion chamber 12 formed with top deck, be distributed in following current heat transfer tube 18, decline gas 2 first flows from top to bottom with reaction gas in beds and flows heat exchange in following current heat transfer tube 18, remove the partial heat of beds 16, reduce the temperature of bed 16, decline gas 2 enters countercurrent flow pipe 17 at upstream with being communicated with in air cavity 20 of downdraft, ascending gas 3 is first flowing from down to up and reaction gas countercurrent flow in beds in countercurrent flow pipe 17, bed temperature declines further, bed temperature is distributed more balanced, unstripped gas 4 after heat exchange is introduced into catalyzer upper packing layers 15, upper packing layers 15 Raw gas fully mix with further preheating after, enter beds 16, reaction gas 5 is in catalyst particle surface generation methane building-up reactions, produce large calorimetric, the rear gas product 6 of reaction enters bottom deck by pore on catalyzer bottom deck 19 and reactor bottom seals the cushion chamber 21 formed, gas product 7 is by housing bottom products export 22 outflow reactor.If can not in time reaction heat be removed by the unstripped gas in concurrent-countercurrent heat transfer tube in beds, beds occurs that temperature raises suddenly, impact reaction normally carry out situation under, quench gas sparger 14 can be started, adopt the direct cold shock of quench gas 8 to regulate the temperature of beds 16.

Embodiment 1

Coke(oven)gas, after conventional purification, is compressed to 3.5MPaG, total sulfur content≤100ppb (v/v), shown in its table composed as follows:

Coke-oven gas composition table

Composition	H 2	CO	CO 2	CH 4	N 2	H 2O	C nH m
								V％	57.6	9.2	3.5	22.7	3.6	1.3	2.1

As shown in Figure 1, methanation catalyst selects conventional methane catalyzer (60%Al to flow process ₂o ₃, the MgO of 20%, the NiO of 20%).Coke(oven)gas is adjusted to 320 DEG C through first stage reactor temperature in regulation system after mixing with circulation gas (coke(oven)gas is 1:1 with the mol ratio of circulation gas), enters one section of adiabatic reactor and carries out methane building-up reactions, and catalyst space velocities adopts 5000h ^-1, maintain 620 DEG C by regulating circulation gas flow control first stage reactor bed hot(test)-spot temperature.After reaction, gas composition is as shown in the table:

One section of gas product composition table

Composition	H 2	CO	CO 2	CH 4	N 2	H 2O	C nH m
								V％	25.8	0.8	1.2	51.6	4.8	15.8	0

This gas is divided into two portions gas after being cooled to 100 DEG C by condensation water diversion system.A part mixes with unstripped gas after recycle compressor compression as circulation gas, and this portion gas amount accounts for 40% (molar content) of the rear gas volume of cooling; Another part directly enters heat exchange methanator in two sections and proceeds methane building-up reactions, and catalyst space velocities adopts 5000h ^-1, controlling beds temperature in is 320 DEG C, makes hot(test)-spot temperature maintain about 430 DEG C.After gas divides water via product cooling water dividing system cools after reaction, obtain synthetic natural gas.This gas composition is as shown in the table:

Synthetic natural gas composition table

Composition	H 2	CO	CO 2	CH 4	N 2	H 2O	C nH m
								V％	23.9	0	0	69.6	6.2	0.3	0

Note: 0 represents lower than limit of detection.

Embodiment 2

Coke(oven)gas, after conventional purification, is compressed to 1.5MPaG, total sulfur content≤100ppb (v/v), and its composition is identical with embodiment 1.As shown in Figure 1, methanation catalyst selects conventional methane catalyzer (50%Al to flow process ₂o ₃, the MgO of 20%, the NiO of 30%).Coke(oven)gas is adjusted to 250 DEG C through first stage reactor temperature in regulation system after mixing with circulation gas (coke(oven)gas is 0.7:1 with the mol ratio of circulation gas), enters one section of adiabatic reactor and carries out methane building-up reactions, and catalyst space velocities adopts 13000h ^-1, maintain 545 DEG C by regulating circulation gas flow control first stage reactor bed hot(test)-spot temperature.After reaction, gas composition is as shown in the table:

One section of gas product composition table

Composition	H 2	CO	CO 2	CH 4	N 2	H 2O	C nH m
								V％	21.5	0.1	0.2	58.9	5.3	14	0

This gas is divided into two portions gas after being cooled to 100 DEG C by condensation water diversion system.A part mixes with unstripped gas after recycle compressor compression as circulation gas, and this portion gas amount accounts for 60% (molar content) of the rear gas volume of cooling; Another part directly enters heat exchange methanator in two sections and proceeds methane building-up reactions, and catalyst space velocities adopts 5500h ^-1, controlling beds temperature in is 250 DEG C, makes hot(test)-spot temperature maintain about 265 DEG C.After gas divides water via product cooling water dividing system cools after reaction, obtain synthetic natural gas.This gas composition is as shown in the table:

Synthetic natural gas composition table

Composition	H 2	CO	CO 2	CH 4	N 2	H 2O	C nH m
								V％	23.9	0	0	69.6	6.2	0.3	0

Embodiment 3

Coke(oven)gas, after conventional purification, is compressed to 2MPaG, total sulfur content≤100ppb (v/v), and its composition is identical with embodiment 1.As shown in Figure 1, methanation catalyst selects conventional methane catalyzer (55%Al to flow process ₂o ₃, the MgO of 20%, the NiO of 25%).Coke(oven)gas is adjusted to 280 DEG C through first stage reactor temperature in regulation system after mixing with circulation gas (coke(oven)gas is 1.4:1 with the mol ratio of circulation gas), enters one section of adiabatic reactor and carries out methane building-up reactions, and catalyst space velocities adopts 20000h ^-1, maintain 545 DEG C by regulating circulation gas flow control first stage reactor bed hot(test)-spot temperature.After reaction, gas composition is as shown in the table:

One section of gas product composition table

Composition	H 2	CO	CO 2	CH 4	N 2	H 2O	C nH m
								V％	21.5	0.1	0.2	58.9	5.3	14	0

This gas is divided into two portions gas after being cooled to 305 DEG C by condensation water diversion system.A part mixes with unstripped gas after recycle compressor compression as circulation gas, and this portion gas amount accounts for 80% (molar content) of the rear gas volume of cooling; Another part directly enters heat exchange methanator in two sections and proceeds methane building-up reactions, and catalyst space velocities adopts 5000h ^-1, controlling beds temperature in is 320 DEG C, makes hot(test)-spot temperature for being in about 335 DEG C.After gas divides water via product cooling water dividing system cools after reaction, obtain synthetic natural gas.This gas composition is as shown in the table

Synthetic natural gas composition table

Composition	H 2	CO	CO 2	CH 4	N 2	H 2O	C nH m
								V％	23.9	0	0	69.6	6.2	0.3	0

Comparative example 1

One, two reactors all adopt adiabatic reactor, and all main operating parameters are all identical with embodiment 1.

Coke(oven)gas, after conventional purification, is compressed to 3.5MPaG, total sulfur content≤100ppb (v/v), and its composition is identical with embodiment 1.Flow process as shown in Figure 1, coke(oven)gas line of pipes is connected to first stage reactor temperature in regulation system M1 entrance, first stage reactor temperature in regulation system M1 outlet is connected to the adiabatic reactor R1 entrance of a section via pipeline, the adiabatic reactor R1 outlet of one section is connected to the first condensation water diversion system M2 entrance via pipeline, first condensation water diversion system M2 outlet is divided into two arms, first arm converges via recycle compressor C1 and coke(oven)gas line of pipes, second arm is connected to the adiabatic reactor R2 ' entrance of two sections via second stage reactor temperature in regulation system M4, two sections of adiabatic reactor R2 ' outlets are connected to the second condensation water diversion system M3 entrance via pipeline, second condensation water diversion system M3 outlet is connected with synthetic natural gas line of pipes.Methanation catalyst selects conventional methane catalyzer (60%Al ₂o ₃, the MgO of 20%, the NiO of 20%).After coke(oven)gas mixes with circulation gas (coke(oven)gas is 1:1 with the mol ratio of circulation gas), be adjusted to 320 DEG C through first stage reactor temperature in regulation system, the adiabatic reactor entering a section carries out methane building-up reactions, and catalyst space velocities adopts 5000h ^-1, maintain 620 DEG C by regulating circulation gas flow control first stage reactor bed hot(test)-spot temperature.After reaction, gas composition is as shown in the table:

One section of gas product composition table

Composition	H 2	CO	CO 2	CH 4	N 2	H 2O	C nH m
								V％	25.8	0.8	1.2	51.6	4.8	15.8	0

This gas is divided into two portions gas after being cooled to 100 DEG C by condensation water diversion system.A part mixes with unstripped gas after recycle compressor compression as circulation gas, and this portion gas amount accounts for 40% (molar content) of the rear gas volume of cooling; Another part is adjusted to 320 DEG C through second stage reactor temperature in regulation system, enters in the adiabatic methanation reactor of two sections and proceeds methane building-up reactions, and catalyst space velocities adopts 5000h ^-1, controlling beds temperature in is 320 DEG C, makes hot(test)-spot temperature maintain about 430 DEG C.After gas divides water via product cooling water dividing system cools after reaction, obtain synthetic natural gas.This gas composition is as shown in the table:

Synthetic natural gas composition table

Composition

H 2

CO

CO 2

CH 4

N 2

H 2O

C nH m

V％

23.9

0

350ppm

69.6

6.2

0.3

0

Compared with embodiment 1, because second segment uses adiabatic reactor, two sections of temperature in regulation systems must be increased regulate temperature in technical process, adding of this system, not only add facility investment, and add the energy consumption of system; CO in gas product ₂content is 350ppm, is unfavorable for the normal operation of follow-up workshop section.

Claims (6)

1. the device of a preparing synthesis gas from coke-oven gas, it is characterized in that this device comprises: humidity control system (M1), the adiabatic reactor (R1) of one section, first condensation water diversion system (M2), the internal heat exchange type methanator (R2) of two sections, second condensation water diversion system (M3) and recycle compressor (C1), wherein, coke(oven)gas feeding line is connected to one section of adiabatic reactor (R1) entrance via humidity control system (M1), one section of adiabatic reactor (R1) outlet is connected to the entrance of the first condensation water diversion system (M2), first condensation water diversion system (M2) outlet is divided into two branch roads, first branch road converges via recycle compressor (C1) and coke(oven)gas feeding line, second branch road is connected to internal heat exchange type methanator (R2) entrance, internal heat exchange type methanator (R2) outlet is connected to the second condensation water diversion system (M3) entrance, second condensation water diversion system (M3) outlet is connected with synthetic natural gas line of pipes.

2. the device of preparing synthesis gas from coke-oven gas according to claim 1, is characterized in that this device comprises:

Humidity control system (M1), the inlet mouth of this system is connected with coke(oven)gas transfer lime (L1);

One section of adiabatic reactor (R1), the inlet mouth of this reactor (R1) is connected to the air outlet of humidity control system (M1) via second pipe (L2);

First condensation water diversion system (M2), the inlet mouth of this water diversion system (M2) is connected to the air outlet of reactor (R1) via the 3rd pipeline (L3);

Two sections of internal heat exchange type methanators (R2), the inlet mouth of this reactor (R2) is connected to the air outlet of water diversion system (M2) via the 4th pipeline (L4);

Second condensation water diversion system (M3), the air outlet of air outlet and this water diversion system (M3) that the inlet mouth of this water diversion system (M3) is connected to reactor (R2) via the 5th pipeline (L5) is connected with the transport pipe of synthetic natural gas; With

Recycle compressor (C1), wherein from the 4th pipeline (L4), namely the connecting tube between water diversion system (M2) and reactor (R2), separate a branch road i.e. the 6th pipeline (L6) and be connected to the inlet mouth of recycle compressor (C1), and the air outlet of recycle compressor (C1) is connected to coke(oven)gas transfer lime (L1) via the 7th pipeline (L7).

3. the device of preparing synthesis gas from coke-oven gas according to claim 1 and 2, it is characterized in that the internal heat exchange type reactor of two sections comprises reactor shell (11), case top is provided with raw material inlet mouth (9) and quench gas inlet mouth (10), housing bottom is provided with product air outlet (22), housing upper has top deck (13), bottom has bottom deck (19), reactor head sealing is formed with top cushion chamber (12) with top deck, catalyzer bottom deck and reactor bottom seal and form lower buffer chamber (21), quench gas sparger (14) is provided with below top deck, upper packing layers (15) is provided with in quench gas sparger (14) below, what below catalyzer bottom deck, arrange upstream and downdraft is communicated with air cavity (20), bottom packing layer (15) is provided with on catalyzer bottom deck (19), beds (16) is set between upper packing layer and lower packing layer (15), thermopair (23) is set in beds (16), be provided with countercurrent flow pipe (17) and following current heat transfer tube (18) in addition, the top of following current heat transfer tube is arranged in reactor head and seals the cushion chamber formed with top deck, the top of countercurrent flow pipe is on top deck and catalyzer between packing layer, the bottom of following current heat transfer tube (18) and countercurrent flow pipe (17) is arranged in the bottom deck of catalyzer and reactor bottom seals the cushion chamber formed.

4. the device of preparing synthesis gas from coke-oven gas according to claim 3, is characterized in that the bottom of the bottom of countercurrent flow pipe lower than following current heat transfer tube.

5. the device of preparing synthesis gas from coke-oven gas according to claim 3, it is characterized in that quench gas inlet mouth (10) is directly communicated to quench gas sparger (14), quench gas sparger (14) is distributed with many quench gas sparger air outlets.

6. the device of preparing synthesis gas from coke-oven gas according to claim 4, it is characterized in that quench gas inlet mouth (10) is directly communicated to quench gas sparger (14), quench gas sparger (14) is distributed with many quench gas sparger air outlets.