CN101265425A - Method for reducing heat value of gaseous liquefied natural gas - Google Patents

Method for reducing heat value of gaseous liquefied natural gas Download PDF

Info

Publication number
CN101265425A
CN101265425A CNA2008100367301A CN200810036730A CN101265425A CN 101265425 A CN101265425 A CN 101265425A CN A2008100367301 A CNA2008100367301 A CN A2008100367301A CN 200810036730 A CN200810036730 A CN 200810036730A CN 101265425 A CN101265425 A CN 101265425A
Authority
CN
China
Prior art keywords
gas
natural gas
liquefied natural
temperature
methane
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
CNA2008100367301A
Other languages
Chinese (zh)
Other versions
CN101265425B (en
Inventor
高建悦
司兴明
金美华
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Shanghai Gas Co ltd
Original Assignee
SHANGHAI GAS (GROUP)CO Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by SHANGHAI GAS (GROUP)CO Ltd filed Critical SHANGHAI GAS (GROUP)CO Ltd
Priority to CN2008100367301A priority Critical patent/CN101265425B/en
Publication of CN101265425A publication Critical patent/CN101265425A/en
Application granted granted Critical
Publication of CN101265425B publication Critical patent/CN101265425B/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Landscapes

  • Industrial Gases (AREA)

Abstract

The invention relates to a method for reducing the heat value of the gaseous liquefied natural gas. The method comprises the following process steps: firstly, the liquefied natural gas is gasified; secondly, the gasified liquefied natural gas is decompressed; thirdly, the pre-reforming is performed to the gasified liquefied natural gas; fourthly, the pre-reformed gas is reacted in a convector to form reformed gas, and fifthly, the reformed gas treatment is performed. The components of the gasified liquefied natural gas comprises 88.2 to 99.4 percent of firedamp, 0.2 to 7.8 percent of ethane, 0.1 to 3.3 percent of propane and 0.1 to 1.7 percent of butane calculated by volume, and the heat value is 10440 to 10700 Kcal/Nm<3>; the components of the product gas comprises 75.1 to 53.8 percent of fire damp, 14 to 30.8 percent of hydrogen gas, 2.4 to 5.4 percent of carbon monoxide and 1.8 to 3.7 percent of carbon dioxide calculated by volume, the heat value is 7500 to 9000 Kcal/Nm<3>, and the pressure is 3.3 to 6.3 MPa. The method of the invention adopts the converted volume expansion energy of the liquefied natural gas after the heat exchange as the power, and therefore the mechanical equipment, such as a compressor, is saved to supply power to the gasified natural gas; the method adopts the linkage operation and the converging of two different process lines (pressure reduction and heat reduction), and the final product natural gas is obtained.

Description

A kind of method that reduces heat value of gaseous liquefied natural gas
Technical field
The present invention relates to control the calorific value of natural gas liquids (LNG), particularly relate to a kind of method that reduces heat value of gaseous liquefied natural gas.
Background technology
According to the national energy strategic planning, China will be before 2010 in the east several large-scale natural gas liquids receiving stations of coastal construction.Domestic first natural gas liquids receiving station-Guangdong receiving station formally receives from Australian natural gas liquids in June, 2006; The natural gas liquids receiving station in Fujian, Shanghai, Jiangsu, Zhejiang also among building, will begin to receive the natural gas liquids from country variant soon successively at present.Every component of the natural gas liquids of the oil-gas field of country variant and liquefaction process production, gas quality index have nothing in common with each other, calorific value and combustion quality also have nothing in common with each other, different sources of the gas mixes the interchangeability that must consider terminal user's gas-fired equipment at pipe network, therefore require the natural gas supply merchant that unified standard calorific value is provided, to guarantee terminal user's, safety stable with gas.Separate the natural gas liquids light hydrocarbon component and have in the prior art; Processing methodes such as nitrogen injection, air or waste gas in natural gas liquids, but the nitrogen injection cost is higher, dilution air can make the oxygen level in the Sweet natural gas improve, the operating safety that relates to pipeline, select to inject waste gas and need near receiving station, possess the waste gas gas source condition, and in the waste gas carbonic acid gas and moisture can cause corrosive pipeline, shorten pipeline work-ing life.Owing to be that high pressure injects all kinds of gases, then energy consumption increases in addition, and running cost improves; To enter the distance of looped network or Heavenly Stems and Earthly Branches net far because of two or more different natural air-air sources again, various source of the gas proportions change because of pressure and operational throughput change in the pipe-line transportation, are difficult to realize that blending accomplishes that accurate proportioning makes it keep stable burning index and calorific value.Still can't solve at present calorific value control, also can't formulate unified liquefied natural gas product calorific value standard range at the various natural gas liquids of usefulness.
The gaseous liquefied natural gas Trade Measures mode of existing national regulation is a volume metering; Among the standard GB 17820-1999 " Sweet natural gas " that carries out in the relevant technical indicator of two class gas the calorific value index much smaller than the calorific value of the various natural gas liquids of present import.
Summary of the invention
In view of the foregoing, the invention provides a kind of method that reduces heat value of gaseous liquefied natural gas.Present method adopts two different process routes (decompression, reduction of heat) to cooperate coordinated operation, obtains the finished product gaseous liquefied natural gas after converging, and the amount of the component of gaseous liquefied natural gas and the calorific value natural gas liquids by entering bypass reduction of heat device is adjusted control.The heat that is higher than the regulation of national standard can be converted into volume, reach the purpose of calorific value control, the energy consumption of this method self is below 2%, and solve oxygen level height in the prior art simultaneously, pipeline is perishable, energy consumption is high and calorific value, burning index are difficult to problems such as control.
Method of the present invention realizes by following process steps:
Step 1. liquefied natural gas gasifying
The main component that is stored in the low-temperature liquefaction Sweet natural gas storage tank is the natural gas liquids of methane, ethane, propane and butane, in gasifier with the water indirect heat exchange, the heat absorption back is liquid to be gaseous state in a disguised form, about 600 times of volumetric expansion, gaseous liquefied natural gas directly enters gas pipe line, and the covert volumetric expansion after the natural gas liquids heat exchange can be as the power of next step.
The decompression of step 2. gaseous liquefied natural gas
With pressure is the unstripped gas of 4.0~7.0MPa, its component is that the gaseous liquefied natural gas of methane, ethane, propane and butane is divided into two strands of gaseous liquefied natural gas, and wherein one gaseous liquefied natural gas gives over to stand-by by the gaseous liquefied natural gas that comes out after the pressure regulator valve decompression.
Step 3. gaseous liquefied natural gas pre-inversion
Another strand gaseous liquefied natural gas is further divided into two strands of gaseous liquefied natural gas of A, B after reducing pressure by variable valve, wherein B thigh gaseous liquefied natural gas enters converter as heating fuel after the pressure regulator valve decompression, the gas fume after burning temperature is 850~1000 ℃, and flue gas enters flue; The hot flue gas that A-share gaseous liquefied natural gas and converter come out is by the preheating heat exchanger preheating, temperature reaches 450~600 ℃, A-share gaseous liquefied natural gas after the preheating and temperature are that 450~550 ℃ superheated vapour mixes back composition gas mixture, the water of gas mixture and the mass ratio of carbon are 1.5~2.0: 1, gas mixture enters pre-converter, the aspect ratio of pre-converter is 3~5: 1, and the filling nickel content is that (carrier is Al for the nickel catalyst of 50~70 volume % in the pre-converter 2O 3), under the effect of catalyzer, reaction obtains the prerotation gasification, and the component of prerotation gasification is the dry gas and the unreacted water vapour of methane, hydrogen, carbon monoxide and carbonic acid gas, and prerotation gasification dry gas calorific value is 7500~8100Kcal/Nm 3, temperature is 450~550 ℃, pressure is 3.8~6.9Mpa.
Step 4. prerotation gasification enters the converter reaction and generates reforming gas
Prerotation gasification and another part superheated vapour are formed gas mixture, and the water of gas mixture and the mass ratio of carbon are 2.5~4.0: 1, and gas mixture enters converting furnace, and the filling nickel content is that (carrier is Al for the nickel catalyst of 6.5~12 volume % in the boiler tube 2O 3), under the catalysis of catalyzer, the methane in the prerotation gasification further reaction is cracked into carbon monoxide, carbonic acid gas and hydrogen.The component of reaction back reforming gas is dry gas and the unreacted water vapour of being made up of methane, hydrogen, carbon monoxide and carbonic acid gas, and reforming gas dry gas calorific value is 3500~3900Kcal/Nm 3, temperature is 750~850 ℃, pressure is 3.3~6.7Mpa.
The cooling of step 5. reforming gas, processed
Reforming gas enters the waste heat boiler of being made up of waste heat exchanger and drum, and temperature is reduced to 250~280 ℃, and reforming gas is by cooling heat exchanger and further cooling and dehydration of water trap, and the water of condensation that water trap is discharged returns water inlet system.Reforming gas temperature after the dehydration is reduced to 20~40 ℃, be blended into product gas on demand mutually by gaseous liquefied natural gas stand-by in pressure regulator valve step-down and the step 1 again, product gas enters the downstream gas distributing system from product gas outlet, and the calorific value of product gas is 7500~9000Kcal/Nm 3
The component by volume of the gaseous liquefied natural gas of 4.0~7.0MPa of the present invention is a methane 88.2~99.4%, ethane 0.2~7.8%, and propane 0.1~3.3%, butane 0.1~1.7%, calorific value are 10440~10700Kcal/Nm 3The component by volume of prerotation gasification dry gas is a methane 76~79%, hydrogen quality 16~18%, and carbon monoxide 0.1~0.6%, carbonic acid gas 4.0~6.0%, calorific value are 7500~8100Kcal/Nm 3, temperature is 450~550 ℃, pressure is 3.8~6.9Mpa; The component by volume of reforming gas dry gas is a methane 13.0~14.0%, hydrogen 66~67%, and carbon monoxide 11.0~12.0%, carbonic acid gas 8.0~9.0%, calorific value are 3600~3700Kcal/Nm 3, temperature is 750~850 ℃, pressure is 5.8~6.2Mpa; The component by volume of product gas is a methane 75.1~53.8%, hydrogen 14~30.8%, and carbon monoxide 2.4~5.4%, carbonic acid gas 1.8~3.7%, calorific value are 7500~9000Kcal/Nm 3, pressure is 3.3~6.3Mpa.
Temperature of the present invention is the waste heat boiler that 750~850 ℃ reforming gas enters waste heat exchanger and drum composition, utilize the waste heat heating deionization soft water production high pressure steam of reforming gas, high-pressure steam pressure is 3.3~6.9Mpa, temperature is 240~290 ℃, it is 450~550 ℃ that high pressure steam entered the superheat steam temperature that heat exchanger obtains after overheated, and superheated vapour is mainly pre-converter and converter provides reaction required steam.
B thigh gaseous liquefied natural gas of the present invention enters converter as heating fuel gas after the pressure regulator valve decompression, the flue-gas temperature of fuel gas after the converter internal combustion is 850~1000 ℃, the flue gas flue, by afterheat heat exchanger the A-share gaseous liquefied natural gas is carried out preheating, the flue-gas temperature after the heat exchange is reduced to 600~700 ℃, entered heat exchanger heating high-pressure steam, obtain 450~550 ℃ superheated vapour, flue-gas temperature is reduced to 160~180 ℃, by the induced draft fan emptying.
Beneficial effect of the present invention
1. method of the present invention has utilized the covert volumetric expansion after the natural gas liquids heat exchange to provide power thereby saved mechanical means such as use compressor to gaseous natural gas as power.
2. present method adopts two different process routes (decompression, reduction of heat) to cooperate coordinated operation, obtains the finished product Sweet natural gas after converging, and the amount of the component of product gas and the calorific value natural gas liquids by entering bypass reduction of heat device is adjusted control.
3. present method heat provides by the combustion parts gaseous liquefied natural gas, and all steam and steam superheating provide by heat exchange by reforming gas, fume afterheat, and the gaseous liquefied natural gas that enters hydrocarbon steam conversion reaction pre-inversion section is provided by fume afterheat.
This method is to utilize the expansion energy of gas after liquid transferpump of natural gas liquids and the heat exchange in sum, reach thermal equilibrium through the part pre-inversion, process gas all returns original device, by process control, make liquefied natural gas product gas by volume contain hydrogen more than 5%, help to improve combustion quality; The heat that will be higher than Sweet natural gas national standard 15%~40% is converted into volume; This method can be regulated the calorific value and the burning index of control liquefied natural gas product gas, carries out modifiedly thereby reach natural gas liquids to quality parameter scopes such as various different calorific values, realizes the unified purpose of gaseous liquefied natural gas product application standard.This method and system can save mechanical supercharging equipment such as using compressor fully.
Description of drawings
Fig. 1 is a process flow sheet of the present invention.
Fig. 2 is the process flow sheet of reduction of heat device of the present invention.
Number in the figure is represented: 1-raw material gas inlet, 2-pressure regulator valve, 3-reliever, 4-pressure regulator valve, 5-reduction of heat device, 6-pressure regulator valve, 7-product gas outlet, 8-drum, the 9-waste heat exchanger, the 10-high pressure steam, 11-crosses heat exchanger, the 12-superheated vapour, the 13-pressure regulator valve, 14-preheating heat exchanger, 15-converter, the 16-pre-converter, 17-cooling heat exchanger, 18,18 '-water trap, the 19-gas blower, 20-induced draft fan, 21-reducing valve.
Embodiment
For better implement the present invention, specify below by example, but protection scope of the present invention is not subjected to the qualification of embodiment content.
Embodiment 1:
Present embodiment is 1,118 ten thousand Nm to air demand 3The gaseous liquefied natural gas of/day adopts the present invention to carry out the calorific value adjustment, and adjusted calorific value is 9000Kcal/Nm 3The main component of gaseous liquefied natural gas is: methane 91.2%, ethane 4.4%, propane 2.9%, butane 1.3%, other 0.2%, calorific value is 10570Kcal/Nm 3Concrete technical process and processing condition:
1. liquefied natural gas gasifying
The main component that is stored in the low-temperature liquefaction Sweet natural gas storage tank is the natural gas liquids of methane, ethane, propane and butane, in gasifier with the water indirect heat exchange, the heat absorption back is liquid to be gaseous state in a disguised form, about 600 times of volumetric expansion, and gaseous liquefied natural gas directly enters gas pipe line.Covert volumetric expansion after the natural gas liquids heat exchange can be as the power of next step.
2. gaseous liquefied natural gas decompression
Gaseous liquefied natural gas [1] pressure is 6.5MPa, and flow is 46.58 ten thousand Nm 3/ h, major ingredient with volume percent count methane 91.2%, ethane 4.4%, propane 2.9%, butane 1.3%, other 0.2%, calorific value is 10570Kcal/Nm 3This portion gas is divided into two strands of materials, and a part is by stand-by after pressure regulator valve [2] voltage stabilizing.
3. gaseous liquefied natural gas pre-inversion
The part that gaseous liquefied natural gas advances reduction of heat device [5] is divided into two strands of A, B, wherein B thigh gas enters converter [15] as heating fuel by pressure regulator valve [13] decompression, the hot flue gas that A-share gas and converter [15] come out carries out heat exchange by preheating heat exchanger [14], temperature after the preheating is 500~550 ℃, gas after the preheating and overheated after water vapour [12] mix, superheated vapo(u)r [12] temperature is 450~550 ℃, and flow is 55T/h.Mix the gas mixture of forming the back and enter pre-converter [16] reaction, pre-transform teactor is cylindrical tube shape, fixed-bed reactor, aspect ratio: 3~5: 1, filling nickel content is 50%~70% nickel catalyst in the reactor, steam and methane are with 450~550 ℃ temperature, 1.5~2: go out under 1 water carbon mass ratio is enterprising, obtain the prerotation gasification.The dry gas major ingredient of prerotation gasification is counted methane 77.7%, hydrogen 17.2%, carbon monoxide 0.3%, carbonic acid gas 4.8% with volume percent, and calorific value is 7900Kcal/Nm 3, 450~500 ℃ of temperature, pressure 6.3~6.4MPa, flow 4.81 ten thousand Nm 3/ h.The prerotation gasification also contains unreacted water vapour 52T/h in addition.
4. converter transforms
Prerotation gasification and unreacted water vapour and another part superheated vapo(u)r [12] are mixed into converter [15] charging, and the water of gas mixture and the mass ratio of carbon are 2.5~4.0: 1.The amount of superheated vapo(u)r [12] is 16T/h, enters converter [15] boiler tube after pre-inversion G﹠W steam mixes, and issues biochemical reaction in the effect of nickel catalyst, and methane wherein further reaction is cracked into carbon monoxide and carbonic acid gas, reduces calorific value.Reacted reforming gas dry gas part major ingredient is counted methane 13.4%, hydrogen 66.9%, carbon monoxide 11.6%, carbonic acid gas 8.1% with volume percent, and calorific value is 3660Kcal/Nm 3, 750~850 ℃ of temperature, pressure 5.8~6.2MPa, flow 12.29 ten thousand Nm 3/ h.Also has unreacted water vapour 49T/h in addition.
The heat of converter is provided in converter [15] internal combustion by fuel natural gas, and combustion air is sent in the converter [15] combustion-supporting by gas blower [19], and fuel gas is in the burner hearth internal combustion, and the gas fume after burning temperature is 850~1000 ℃, and flue gas enters flue.
5. waste heat recovery
Reforming gas enters waste heat exchanger [9], and waste heat exchanger and drum [8] are formed waste heat boiler, utilizes the waste heat heating deionization soft water production high pressure steam [10] of reforming gas, and high pressure steam [10] pressure is 6.5MPa, and temperature is 285 ℃, and flow is 130T/h.High pressure steam [10] is sent a part and is low-pressure steam by reducing valve [21] decompression from drum [8], use to do him.Another part flow is 71T/h, and it is overheated to enter heat exchanger [11].450~550 ℃ of vapour temperatures after overheated, superheated vapo(u)r [12] are mainly pre-converter [16] and converter [15] provides reaction required steam.
Flue gas enters the gaseous liquefied natural gas of pre-converter [16] by preheating heat exchanger [14] preheating in flue.Flue-gas temperature is reduced to 600~700 ℃ after the heat exchange.This part flue gas was passing through heat exchanger [11] heating high-pressure steam [10].After this flue gas also can further carry out heat exchange with combustion air, makes temperature be reduced to 160~180 ℃ by induced draft fan [20] emptying.
6. reforming gas is handled
Behind the reforming gas process waste heat exchanger [9], temperature drops to 250~280 ℃, separate out water of condensation by water trap [18], the reforming gas of preliminary hydro-extraction is by cooling heat exchanger [17] and the further cooled dehydrated of water trap [18 '], and the water of condensation that water trap [18,18 '] is discharged turns back to the waste heat boiler water inlet system.Synthetic gas temperature after the dehydration is reduced to 20~40 ℃, be depressurized to 5.5MPa by pressure regulator valve [6] again, the composition of synthetic gas is counted methane 13.4%, hydrogen 66.9%, carbon monoxide 11.6%, carbonic acid gas 8.1%, calorific value 3660Kcal/Nm with volume percent 3Synthetic gas and another part gaseous liquefied natural gas material [3] mix, and obtaining the adjusted product gas of calorific value [7] flow is 54.04 ten thousand Nm 3/ h.Air demand is 1,297 ten thousand Nm after the calorific value adjustment 3/ day, gas composition is: methane 73.5%, ethane 3.4%, propane 2.2%, butane 1.0%, hydrogen 15.5%, carbon monoxide 2.7%, carbonic acid gas 1.9%, calorific value 9000Kcal/Nm3.The stand-by decompression gas of voltage stabilizing is blended into product gas on demand in synthetic gas and the above-mentioned steps 2, and the product airshed is 54.04Nm 3/ h, calorific value are 9000Kcal/Nm 3Product gas is sent into the downstream gas distributing system from product gas outlet [7].
Result of implementation sees Table 1.
Table 1.
Component Unit Unstripped gas Decompression gas A, B gas Synthetic gas Product gas The prerotation gasification Reforming gas
Methane 91.2 13.4 73.5 77.7 13.4
Ethane 4.4 3.4
Propane 2.9 2.2
Butane 1.3 1
Hydrogen 66.9 15.5 17.2 66.9
Carbon monoxide 11.6 2.7 0.3 11.6
Carbonic acid gas 8.1 1.9 4.8 8.1
Other 0.2
Calorific value kcal/Nm 3 10570 3660 9000 7900 3660
Flow Ten thousand Nm 3/h 46.58 41.75 4.83 12.29 54.04 4.81 12.29
Pressure MPa 6.8 5.5 6.5 5.7-6.1 5.5 6.3-6.4 5.8-6.2
Temperature 20-40 450-550 750-850
Water vapour T/h 52 49
Embodiment 2:
Present embodiment is 1,118 ten thousand Nm to air demand 3The LNG gas of/day adopts the present invention to carry out the calorific value adjustment, and adjusted calorific value is 7500Kcal/Nm 3The main component of LNG gas with volume percent count methane 91.2%, ethane 4.4%, propane 2.9%, butane 1.3%, other 0.2%, calorific value is 10570Kcal/Nm 3Concrete technical process and processing condition:
1. liquefied natural gas gasifying technology is with embodiment 1
2. gaseous liquefied natural gas decompression
Unstripped gas enters reduction of heat device [5] component with embodiment 1, and flow is 110,000 Nm 3/ h, pressure are 6.5MPa.This portion gas is divided into two strands of materials, and a part is by stand-by after pressure regulator valve [2] voltage stabilizing.
3. gaseous liquefied natural gas pre-inversion
Gaseous liquefied natural gas advances the technology of part of reduction of heat device [5] with embodiment 1, to be divided into two strands of A, B, wherein B thigh gas enters converter [15] as heating fuel by pressure regulator valve [13] decompression, the hot flue gas that A-share gas and converter [15] come out carries out heat exchange by preheating heat exchanger [14], and the temperature after the preheating is 500~550 ℃.Gas after the preheating and overheated after water vapour [12] mix, superheated vapo(u)r [12] temperature is 450~550 ℃, flow is 126T/h.Mix the gas mixture of forming the back and enter pre-converter [16] reaction, pre-transform teactor is cylindrical tube shape, fixed-bed reactor, aspect ratio: 3~5: 1, filling nickel content is 50%~70% nickel catalyst in the reactor, steam and methane are with 450~550 ℃ temperature, 1.5~2: go out under 1 water carbon mass ratio is enterprising, obtain the prerotation gasification.The dry gas major ingredient of prerotation gasification: methane 77.7%, hydrogen 17.2%, carbon monoxide 0.3%, carbonic acid gas 4.8%, calorific value are 7900Kcal/Nm 3, 450~500 ℃ of temperature, pressure 6.3~6.4MPa, flow 10.95 ten thousand Nm 3/ h.The prerotation gasification also contains unreacted water vapour 119T/h in addition.
4. converter transforms
Prerotation gasification and unreacted water vapour and another part superheated vapo(u)r [12] are mixed into converter [15] charging, and the water of gas mixture and the mass ratio of carbon are 2.5~4.0: 1.The amount of superheated vapo(u)r [12] is 16T/h, enters converter [15] boiler tube after pre-inversion G﹠W steam mixes, and issues biochemical reaction in the effect of nickel catalyst, and methane wherein further reaction is cracked into carbon monoxide and carbonic acid gas, reduces calorific value.Reacted reforming gas dry gas part major ingredient is: methane 13.4%, hydrogen 66.9%, carbon monoxide 11.6%, carbonic acid gas 8.1%, calorific value are 3660Kcal/Nm 3, 750~850 ℃ of temperature, pressure 5.8~6.2MPa, flow 27.67 ten thousand Nm 3/ h.Also has unreacted water vapour 110T/h in addition.The heat of converter is provided in converter [15] internal combustion by fuel natural gas, and combustion air is sent in the converter [15] combustion-supporting by gas blower [19], and fuel gas is in the burner hearth internal combustion, and the gas fume after burning temperature is 850~1000 ℃, and flue gas enters flue.
5. waste heat recovery
Reforming gas enters waste heat exchanger [9], and waste heat exchanger [9] is formed waste heat boiler with drum [8], utilizes the waste heat heating deionization soft water production high pressure steam [10] of reforming gas, and high pressure steam [10] pressure is 6.5MPa, and temperature is 285 ℃, and flow is 295T/h.High pressure steam [10] is sent a part and is low-pressure steam by reducing valve [21] decompression from drum, use to do him.Another part flow is 162T/h, and it is overheated to enter heat exchanger [11].450~550 ℃ of vapour temperatures after overheated, superheated vapo(u)r [12] are mainly pre-converter [16] and converter [15] provides reaction required steam.
Flue gas enters the gaseous liquefied natural gas of pre-converter [16] by preheating heat exchanger [14] preheating in flue.Flue-gas temperature is reduced to 600~700 ℃ after the heat exchange.This part flue gas was passing through heat exchanger [11] heating high-pressure steam [10].After this flue gas also can further carry out heat exchange with combustion air, makes temperature be reduced to 160~180 ℃ by induced draft fan [20] emptying.
6. reforming gas is handled
Behind the reforming gas process waste heat exchanger [9], temperature drops to 250~280 ℃, separate out water of condensation by water trap [18], the reforming gas of preliminary hydro-extraction is by cooling heat exchanger [17] and the further cooled dehydrated of water trap [18 '], and the water of condensation that water trap [18,18 '] is discharged turns back to the waste heat boiler water inlet system.Synthetic gas temperature after the dehydration is reduced to 20~40 ℃, be depressurized to 5.5MPa by pressure regulator valve [6] again, the composition of synthetic gas is counted methane 13.4%, hydrogen 66.9%, carbon monoxide 11.6%, carbonic acid gas 8.1%, calorific value 3660Kcal/Nm with volume percent 3Synthetic gas and another part gaseous liquefied natural gas decompression gas [3] mix, and obtaining the adjusted product gas of calorific value [7] flow is 63.25 ten thousand Nm 3/ h.Air demand is 1,518 ten thousand Nm after the calorific value adjustment 3/ day, gas composition is: methane 57.2%, ethane 2.5%, propane 1.6%, butane 0.7%, hydrogen 29.3%, carbon monoxide 5.2%, carbonic acid gas 3.5%, calorific value 7500Kcal/Nm3.The stand-by decompression gas of voltage stabilizing is blended into product gas on demand in synthetic gas and the above-mentioned steps 2, and the product airshed is 63.25Nm 3/ h, calorific value are 7500Kcal/Nm 3Product gas is sent into the downstream gas distributing system from product gas outlet [7].
Result of implementation sees Table 2.
Table 2
Component Unit Unstripped gas Decompression gas A, B gas Synthetic gas Product gas The prerotation gasification Reforming gas
Methane 91.2 13.4 57.2 77.7 13.4
Ethane 4.4 2.5
Propane 2.9 1.6
Butane 1.3 0.7
Hydrogen 66.9 29.3 17.2 66.9
Carbon monoxide 11.6 5.2 0.3 11.6
Carbonic acid gas 8.1 3.5 4.8 8.1
Other 0.2
Calorific value kcal/Nm 3 10570 3660 7500 7900 3660
Flow Ten thousand Nm 3/h 46.58 35.58 11 27.67 63.25 10.95 27.67
Pressure MPa 6.8 5.5 6.5 5.7-6.1 5.5 6.3-6.4 5.8-6.2
Temperature 20-40 450-550 750-850
Water vapour T/h 119 110

Claims (5)

1. method that reduces heat value of gaseous liquefied natural gas is characterized in that this method comprises following processing step:
(1) liquefied natural gas gasifying
The main component that is stored in the low-temperature liquefaction Sweet natural gas storage tank is the natural gas liquids of methane, ethane, propane and butane, in gasifier with the water indirect heat exchange, the heat absorption back is liquid to be gaseous state in a disguised form, about 600 times of volumetric expansion, gaseous liquefied natural gas directly enters gas pipe line, and the covert volumetric expansion after the natural gas liquids heat exchange can be as the power of next step;
(2) gaseous liquefied natural gas decompression
With pressure is that the major ingredient of 4.0~7.0MPa is that the gaseous liquefied natural gas of methane, ethane, propane and butane is divided into two strands of gaseous state materials, and wherein one gaseous liquefied natural gas material is by stand-by after pressure regulator valve [2] voltage stabilizing;
(3) gaseous liquefied natural gas pre-inversion
Another strand gaseous liquefied natural gas material is after pressure regulator valve [4] decompression, enter reduction of heat device [5], be divided into A, two strands of gaseous state materials of B, wherein B thigh gaseous liquefied natural gas enters converter [15] as heating fuel gas after pressure regulator valve [13] decompression, the A-share gaseous liquefied natural gas is after preheating heat exchanger [14] preheating, temperature reaches 500~550 ℃, gaseous state material after the preheating and 450~550 ℃ of overheated steams [12] mix, the water in the gas mixture and the mass ratio of carbon are 1.5~2.0: 1, gas mixture enters pre-converter [16], reaction obtains the prerotation gasification under the catalysis of nickel catalyst, and the prerotation gasification is mainly by methane, hydrogen, dry gas that carbon monoxide and carbonic acid gas are formed and unreacted water vapour are formed;
(4) the prerotation gasification reacts in converter [15] and generates reforming gas
Prerotation gasification and another part superheated vapour [12] mix, the water in the gas mixture and the mass ratio of carbon are 2.5~4.0: 1, gas mixture enters converter [15], under the catalysis of nickel catalyst, methane in the prerotation gasification further is cracked into carbon monoxide and carbonic acid gas and hydrogen, reduce calorific value, dry gas and unreacted water vapour that reacted reforming gas is made up of methane, hydrogen, carbon monoxide and carbonic acid gas are formed;
(5) reforming gas is handled
Reforming gas enters the waste heat boiler of being made up of waste heat exchanger [9] and drum [8], temperature drops to 250~280 ℃, reforming gas is by cooling off cooling heat exchanger [17] and water trap [18], [18 '], dehydration, the water of condensation that water trap [18 '] is discharged returns the water inlet system of waste heat boiler, reforming gas temperature after the dehydration is reduced to 20~40 ℃, reforming gas by pressure regulator valve [13] step-down after with step (1) in stand-by gaseous liquefied natural gas be blended into product gas on demand mutually, the calorific value of product gas is 7500~9000Kcal/Nm 3, product gas enters the downstream gas distributing system from product gas outlet [7].
2. method according to claim 1, it is characterized in that: described pressure is that the composition by volume of the gaseous liquefied natural gas of 4.0~7.0MPa is a methane 88.2~99.4%, ethane 0.2~7.8%, propane 0.1~3.3%, butane 0.1~1.7%, calorific value are 10440~10700Kcal/Nm 3The component by volume of prerotation gasification dry gas is a methane 76~79%, hydrogen quality 16~18%, and carbon monoxide 0.1~0.6%, carbonic acid gas 4.0~6.0%, calorific value are 7500~8100Kcal/Nm 3, temperature is 450~550 ℃, pressure is 3.8~6.9Mpa; The component by volume of reforming gas dry gas is a methane 13.0~14.0%, hydrogen 66~67%, and carbon monoxide 11.0~12.0%, carbonic acid gas 8.0~9.0%, calorific value are 3600~3700Kcal/Nm 3, temperature is 750~850 ℃, pressure is 5.8~6.2Mpa; The component by volume of product gas is a methane 75.1~53.8%, hydrogen 14~30.8%, and carbon monoxide 2.4~5.4%, carbonic acid gas 1.8~3.7%, calorific value are 7500~9000Kcal/Nm 3, pressure is 3.3~6.3Mpa.
3. according to claims 1 or 2 described methods, it is characterized in that: the nickel catalyst in the step (2) in the pre-converter [16] be nickel content be 50~70 volume % be the catalyzer of carrier with the aluminium sesquioxide; Nickel catalyst in the step (3) in the converter [15] be nickel content be 6.5~12 volume % be the catalyzer of carrier with the aluminium sesquioxide.
4. according to right 1 or 2 described methods, it is characterized in that in the step (4) that 750~850 ℃ reforming gas enters the waste heat boiler of being made up of waste heat exchanger [9] and drum [8] and carries out heat exchange, utilize waste heat to add hot deionized water production high pressure steam [10], the pressure of high pressure steam [10] is 3.3~6.9MPa, temperature is 240~290 ℃, high pressure steam [10] entered further heating of heat exchanger [11], obtained 450~550 ℃ superheated vapour [12].
5. method according to claim 1 and 2, it is characterized in that B thigh gaseous liquefied natural gas material enters converter [15] as heating fuel gas in the step (2) after pressure regulator valve [13] decompression, the flue-gas temperature of fuel gas after converter [15] internal combustion is 850~1000 ℃, the flue gas flue, by preheating heat exchanger [14] A-share gaseous liquefied natural gas material is carried out preheating, flue-gas temperature after the heat exchange is reduced to 600~700 ℃, entered heat exchanger [11] heating high-pressure steam [10], obtain 450~550 ℃ superheated vapour [12], flue-gas temperature is further reduced to 160~180 ℃ again, by drawing phoenix machine [20] emptying.
CN2008100367301A 2008-04-28 2008-04-28 Method for reducing heat value of gaseous liquefied natural gas Active CN101265425B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2008100367301A CN101265425B (en) 2008-04-28 2008-04-28 Method for reducing heat value of gaseous liquefied natural gas

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN2008100367301A CN101265425B (en) 2008-04-28 2008-04-28 Method for reducing heat value of gaseous liquefied natural gas

Publications (2)

Publication Number Publication Date
CN101265425A true CN101265425A (en) 2008-09-17
CN101265425B CN101265425B (en) 2011-04-13

Family

ID=39988118

Family Applications (1)

Application Number Title Priority Date Filing Date
CN2008100367301A Active CN101265425B (en) 2008-04-28 2008-04-28 Method for reducing heat value of gaseous liquefied natural gas

Country Status (1)

Country Link
CN (1) CN101265425B (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102762700A (en) * 2009-12-18 2012-10-31 道达尔公司 Method for producing liquefied natural gas having an adjusted higher calorific power
CN106318499A (en) * 2016-10-11 2017-01-11 海盐埃弗瑞新能源科技有限公司 Carbon hydrocarbon gas for combustion

Family Cites Families (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2000079179A1 (en) * 1999-06-23 2000-12-28 Chicago Bridge & Iron Company System and apparatus for condensing boil-off vapor from a liquified natural gas container
US6564579B1 (en) * 2002-05-13 2003-05-20 Black & Veatch Pritchard Inc. Method for vaporizing and recovery of natural gas liquids from liquefied natural gas
EP1695004A1 (en) * 2003-12-15 2006-08-30 BP Corporation North America Inc. Systems and methods for vaporization of liquefied natural gas
CN1648219A (en) * 2004-01-20 2005-08-03 上海浦东新区海科(集团)公司 City natural gas of mixed air and light hydrocarbon gas and its producing method

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102762700A (en) * 2009-12-18 2012-10-31 道达尔公司 Method for producing liquefied natural gas having an adjusted higher calorific power
CN106318499A (en) * 2016-10-11 2017-01-11 海盐埃弗瑞新能源科技有限公司 Carbon hydrocarbon gas for combustion

Also Published As

Publication number Publication date
CN101265425B (en) 2011-04-13

Similar Documents

Publication Publication Date Title
Juangsa et al. Highly energy-efficient combination of dehydrogenation of methylcyclohexane and hydrogen-based power generation
Ertesvåg et al. Exergy analysis of a gas-turbine combined-cycle power plant with precombustion CO2 capture
CN109179320B (en) Natural gas on-site hydrogen production device and method
CN107359361B (en) Skid-mounted integrated device and method for hydrogen production by natural gas and integrated combined supply of heat, electricity and cold with proton exchange membrane fuel cell
US7718159B2 (en) Process for co-production of electricity and hydrogen-rich gas steam reforming of a hydrocarbon fraction with input of calories by combustion with hydrogen in situ
CN101274746A (en) Reforming system for combined cycle plant with partial CO2 capture
RU2467187C2 (en) Method of operating gas turbine unit
WO2022257282A1 (en) System and method for reducing carbon dioxide emission of coal-fired unit by using ammonia combustion
CN108428914B (en) Device and method for treating raw material gas of SOFC power generation system
CN103975139A (en) Internal combustion engine, in particular a stationary gas engine, comprising a combustion chamber
CN115030840B (en) Zero-emission ammonia-hydrogen engine fuel injection system and operation method
JP5557255B2 (en) Reactant manufacturing method and manufacturing system using exhaust heat and renewable energy
CN101265425B (en) Method for reducing heat value of gaseous liquefied natural gas
CN113339165A (en) System and method for reducing carbon dioxide emission of gas generator set by using ammonia combustion
CN110921623A (en) Hydrogen separation and water gas reforming integrated high-pressure hydrogen production system and method thereof
Su et al. Novel ammonia-driven chemically recuperated gas turbine cycle based on dual fuel mode
CN108557764B (en) Anhydrous hydrogen production process
CN104344414B (en) Waste heat recovery device and waste heat recovery method
US9957888B2 (en) System for generating syngas and an associated method thereof
US20100199682A1 (en) Process for the production of hydrogen with total recovery of co2 and reduction of unconverted methane
RU2587736C1 (en) Plant for utilisation of low-pressure natural and associated oil gases and method for use thereof
Phillips et al. Enhanced gas turbine combustor performance using H2-enriched natural gas
EP3906293B1 (en) Method for hydrogen enrichment of natural gas in supercritical water
CN114014270A (en) Modularized natural gas reforming hydrogen production machine and hydrogen production method thereof
WO2007006236A1 (en) A production method for civil mixed fuel gas consisting of light hydrocarbons mixed with air and coal gas

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C14 Grant of patent or utility model
GR01 Patent grant
TR01 Transfer of patent right
TR01 Transfer of patent right

Effective date of registration: 20230222

Address after: 200120 Room 1009, No. 958, Lujiazui Ring Road, Free Trade Pilot Zone, Pudong New Area, Shanghai

Patentee after: Shanghai Gas Co.,Ltd.

Address before: 200021, 1 Fuxing Road, Shanghai, Luwan District

Patentee before: SHANGHAI GAS GROUP Co.,Ltd.