CN102862957B - Application and preparation of high-stability oxygen carrier in chemical link circulation hydrogen production - Google Patents
Application and preparation of high-stability oxygen carrier in chemical link circulation hydrogen production Download PDFInfo
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- CN102862957B CN102862957B CN201110188461.2A CN201110188461A CN102862957B CN 102862957 B CN102862957 B CN 102862957B CN 201110188461 A CN201110188461 A CN 201110188461A CN 102862957 B CN102862957 B CN 102862957B
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Abstract
The invention discloses application and preparation of a high-stability oxygen carrier in the chemical link circulation hydrogen production. The oxygen carrier is composed of LaNiO3 composite metal oxide with perovskite structure and nickel oxide. The oxygen carrier includes 50%-95% of LaNiO3 composite metal oxide with the perovskite structure and 5%-50% of nickel oxide by weight. In the application of the oxygen carrier in the chemical link circulation hydrogen production, the reaction temperature of the oxygen carrier in fuel is 600-1200 DEG C, and the reaction temperature of the oxygen carrier in steam is 600-1200 DEG C. The oxygen carrier can be prepared by adopting the impregnation method or the citric acid complex one-step method. The oxygen carrier is high in oxygen carrying rate, good in activity and stability, high temperature resistant, high in hydrogen production rate, simple in preparation method and suitable for industrial application.
Description
Technical field
The present invention relates to the application of a kind of oxygen carrier in recycle chemistry chain hydrogen production technology and preparation method, belong to hydrogen production of chemical chain field.
Background technology
The current quick growth along with population, industrialization degree deepen constantly the increase day by day with energy demand, while electric power based on fossil oil is created on and meets energy demand, also very large environmental hazard is brought, wherein the CO that discharges of combustion of fossil fuel
2cause CO in air
2concentration constantly increases, and Greenhouse effect are constantly strengthened, and therefore comes from the CO in fossil fuel combustion process
2control and reduction of discharging receive the close attention of international community.
In order to control with coal be fuel electric power generative process in CO
2discharge, and improve generating efficiency and use the CO such as fuel that other C/H is lower and renewable resources
2control route is compared, CO in the fossil oil power production processes such as coal
2recovery and storage (CCS) be unique efficient manner, can reach in a short time and effectively reduce discharging CO
2but belonging to target CCS three kinds of CO
2discharge-reducing method (before comprising burning, after pure oxygen burning and burning) although and relevant technology can reach CO
2recovery target, but can cause system efficiency reduce and CO
2the increase of cost recovery, makes CO
2recovery technology apply and receive great obstruction.Therefore explore and study novel CO
2recovery technology is for CO in fossil fuel combustion process
2reduction of discharging be significant.
Nineteen eighty-three, Germany scientist Richter and Knoche proposes the concept of burning chemistry chains (chemical looping combustion, CLC) first.This combustion technology and the maximum difference of common combustion technology are the oxygen molecules directly do not used in air, but use the Sauerstoffatom in oxygen carrier to complete the combustion processes of fuel, products of combustion (mainly CO
2and water vapour) can not by the nitrogen dilution in air very high concentrations, almost pure CO can be obtained by simple condensation
2, achieve CO to simple and less energy-consumption
2separation and trapping; In addition, because the operating temperature of fuel reactor and air reactor is relatively low, almost generate without thermal NO x and Quick-type NOx in air reactor, and in fuel reactor, owing to not contacting with oxygen, do not have fuel type NOx to generate.
Hydrogen receives close concern as pollution-free, the eco-friendly economy energy, has purposes widely.In view of the CO of burning chemistry chains method
2interior separation characteristic, the hydrogen manufacturing of applied chemistry chain combustion method also becomes a current study hotspot.Similar with CLC process, complete the regeneration of oxygen carrier using water vapour replacement air as oxygenant introducing air reactor, water vapour is also reduced generation hydrogen simultaneously.Current, in the world a lot of study group Hatano of comprising Japan to solid waste such as polyethylene for fuel NiO and Fe
2o
3deng for the people such as oxygen carrier, Korea S Son are to CH
4for fuel NiO and Fe
2o
3fan L-S for oxygen carrier, the U.S. teaches study group to the Fe taking coal as fuel
2o
3for the CLC hydrogen production process of oxygen carrier etc. is studied.
Oxygen carrier is as medium, circulate between two reactors, ceaselessly the heat that the oxygen in air (water vapour) reactor and reaction generate is delivered to fuel reactor and carries out reduction reaction, therefore the character of oxygen carrier directly affects the operation of whole burning chemistry chains/hydrogen manufacturing.Therefore, high-performance oxygen carrier realizes having CO
2the key of the burning chemistry chains/hydrogen producing technology of enriched character.At present, the oxygen carrier of main research is metal oxygen carrier, and comprise Fe, Ni, Co, Cu, Mn, Cd etc., carrier mainly contains: Al
2o
3, TiO
2, MgO, SiO
2, YSZ etc., also have a small amount of nonmetal oxide as CaSO
4deng.In burning chemistry chains/hydrogen production process, oxygen carrier is in continuous oxygen loss-get oxygen condition, so the activity of oxygen is very important in oxygen carrier.Comparatively speaking, oxygen carrier NiO/NiAl
2o
4(CHO P etc. Fuel, 2004,83 (9)), Fe
2o
3/ Al
2o
3(MATTISSON T etc. Fuel, 2001,80 (13)) and CoO-NiO/YSZ(JIN H G etc. Energy Fuels, 1998,12 (6)) etc. over-all properties is better, but has that oxygen carrier rate is limited, circulating reaction is lower, cannot bear the not high deficiency of higher temperature of reaction, metal oxide dispersity in oxygen carrier.
Summary of the invention
For the deficiencies in the prior art, the invention provides a kind of oxygen carrier for recycle chemistry chain hydrogen production and preparation method thereof, the oxygen carrier rate of this oxygen carrier and hydrogen yield is high, oxygen cycle ability is strong, good stability.
A kind of oxygen carrier, by the LaNiO with perovskite structure
3complex metal oxides and nickel oxide composition, by the weighing scale of final oxygen carrier, have the LaNiO of perovskite structure in this oxygen carrier
3the content of complex metal oxides is 50% ~ 95%, and the content of nickel oxide is 5% ~ 50%.
The application of oxygen carrier of the present invention in recycle chemistry chain hydrogen production, the temperature of reaction of oxygen carrier in fuel is 600 ~ 1200 DEG C, and the temperature of reaction of oxygen carrier in water vapour is 600 ~ 1200 DEG C, and reaction pressure is normal pressure, the fuel used can be solid fuel also can be gaseous fuel, preferred the latter.
Above-mentioned oxygen carrier can be spherical, bar shaped, the suitable shape such as microballoon or abnormity, and particle size is generally 10 μm-2000 μm, and preferred particle size is 50 μm-500 μm.Other suitable inorganic refractory component can be added during use, as aluminum oxide, titanium oxide, magnesium oxide, silicon oxide etc. one or more.
Oxygen carrier of the present invention can adopt pickling process or the preparation of citric acid complex single stage method.Described pickling process has the LaNiO of perovskite structure
3loaded metal nickel on complex metal oxides, incipient impregnation or excessively volume impregnation, then drying, calcination steps obtain described oxygen carrier.
Described citric acid complex single stage method preparation process is: with nickelous nitrate, lanthanum nitrate for presoma, take citric acid as complexing agent, wiring solution-forming mixing and stirring.Then carry out moisture evaporation, the colloidal sol of solution went from clear is transformed into the gel of thickness, obtains described oxygen carrier finally by dry, roasting.
In above-mentioned lemon acid complexing single stage method preparation process, complexing agent and metal ion mol ratio are 1:1 ~ 5:1, are preferably 1:1 ~ 3:1.The mol ratio of metal ion nickel and metal ion lanthanum is 1:1 ~ 5:1, preferred 1.1:1 ~ 3.5:1.The temperature of preparation and stirred solution is 30 ~ 90 DEG C, is preferably 50 ~ 80 DEG C.Stir speed (S.S.) is 100 ~ 500rpm, is preferably 300 ~ 400rpm.Churning time is 3 ~ 8 hours, is preferably 4 ~ 6 hours.Drying temperature is 60 ~ 200 DEG C, is preferably 80 ~ 150 DEG C.Time of drying is 1 ~ 36 hour, is preferably 8 ~ 24 hours.Roasting roasting 2 ~ 15 hours at 400 ~ 1000 DEG C, preferably roasting 3 ~ 8 hours at 600 ~ 900 DEG C.
Chemical chain burning technology oxygen carrier of the present invention contains the LaNiO with perovskite structure
3and nickel oxide, there is the LaNiO of perovskite structure
3complex metal oxides Heat stability is good, not only containing a large amount of lattice oxygen, adsorb oxygen on its abundant Lacking oxygen is also more active, can oxygenated fuel gas, lattice oxygen can supplement the adsorb oxygen constantly consumed simultaneously, after entering oxidation reactor, water vapour reoffers oxygen to uhligite, produces a large amount of hydrogen simultaneously; Nickel oxide oxygen carrier is dispersed in the LaNiO with perovskite structure
3surface or with its composition composite oxides, there is the LaNiO of perovskite structure
3lacking oxygen can play the effect of stable cobalt, solve nickel oxide as the problem that at high temperature there is easily sintering during oxygen carrier.
The present invention adopts citric acid complex method, and control suitable reaction conditions, single stage method prepares the oxygen carrier of high reactivity and high stability, and oxygen carrier prepared by the method is nickel oxide and the LaNiO with perovskite structure
3the composite oxides of composition, nickel oxide particle has the advantage that particle diameter is little, dispersity is high, and strengthens the stabilization of Lacking oxygen to nickel, further increases the anti-caking power of oxygen carrier.
Compared with prior art, hydrogen production of chemical chain oxygen carrier of the present invention has the advantages such as preparation method is simple, active and stability is high, hydrogen output is large, persistent loop ability is strong, and this oxygen carrier can react at a higher temperature.
Accompanying drawing explanation
The X-ray diffractogram of the composite type metallic oxide of Fig. 1 obtained by the embodiment of the present invention 1.
Embodiment
Process and the effect of the inventive method is further illustrated below in conjunction with embodiment.
Embodiment 1
Get 36.3g Ni (NO
3)
26H
2o, puts into the beaker of 500mL, adds the distilled water of 100mL, and then beaker is placed in the water-bath of 80 DEG C, stirring velocity is 400rpm.Get 34.3g La (NO
3)
36H
2o, is placed with in the beaker of 100mL distilled water, is stirred to whole dissolving.Then lanthanum nitrate hexahydrate is added drop-wise in nickel nitrate solution, dropping limit, limit is stirred.Get 40g citric acid, be placed with in the beaker of 100mL and be stirred to whole dissolving, after above-mentioned mixing solutions stirs 30 minutes, add citric acid solution slowly, dropping limit, limit is stirred.Stir after 5 hours, solution has dewatered and has become thick gel, is taken out by gel and puts in the loft drier of 110 DEG C, dried overnight.Then dried uhligite precursor is taken out, be placed in retort furnace, 400 DEG C are risen to from room temperature with the temperature rise rate of 3 DEG C/min, constant temperature calcining 3 hours, rise to 900 DEG C with the temperature rise rate of 10 DEG C/min again, constant temperature calcining 4 hours, obtain complex metal oxides oxygen carrier, wherein the mass content of NiO is 15wt%, LaNiO
3content be 85wt%.
Embodiment 2
Get 48.24g Ni (NO
3)
26H
2o, puts into the beaker of 500mL, adds the distilled water of 100mL, and then beaker is placed in the water-bath of 80 DEG C, stirring velocity is 400rpm.Get 34.3g La (NO
3)
36H
2o, is placed with in the beaker of 100mL distilled water, is stirred to whole dissolving.Then lanthanum nitrate hexahydrate is added drop-wise in nickel nitrate solution, dropping limit, limit is stirred.Get 40g citric acid, be placed with in the beaker of 100mL and be stirred to whole dissolving, after above-mentioned mixing solutions stirs 30 minutes, add citric acid solution slowly, dropping limit, limit is stirred.Stir after 5 hours, solution has dewatered and has become thick gel, is taken out by gel and puts in the loft drier of 110 DEG C, dried overnight.Then dried uhligite precursor is taken out, be placed in retort furnace, 400 DEG C are risen to from room temperature with the temperature rise rate of 3 DEG C/min, constant temperature calcining 3 hours, rise to 900 DEG C with the temperature rise rate of 10 DEG C/min again, constant temperature calcining 4 hours, obtain complex metal oxides oxygen carrier, wherein the mass content of NiO is 25wt%, LaNiO
3content be 75wt%.
Embodiment 3
Get 73.48g Ni (NO
3)
26H
2o, puts into the beaker of 500mL, adds the distilled water of 100mL, and then beaker is placed in the water-bath of 80 DEG C, stirring velocity is 400rpm.Get 34.3g La (NO
3)
36H
2o, is placed with in the beaker of 100mL distilled water, is stirred to whole dissolving.Then lanthanum nitrate hexahydrate is added drop-wise in nickel nitrate solution, dropping limit, limit is stirred.Get 40g citric acid, be placed with in the beaker of 100mL and be stirred to whole dissolving, after above-mentioned mixing solutions stirs 30 minutes, add citric acid solution slowly, dropping limit, limit is stirred.Stir after 5 hours, solution has dewatered and has become thick gel, is taken out by gel and puts in the loft drier of 110 DEG C, dried overnight.Then dried uhligite precursor is taken out, be placed in retort furnace, 400 DEG C are risen to from room temperature with the temperature rise rate of 3 DEG C/min, constant temperature calcining 3 hours, rise to 900 DEG C with the temperature rise rate of 10 DEG C/min again, constant temperature calcining 4 hours, obtain complex metal oxides oxygen carrier, wherein the mass content of NiO is 40wt%, LaNiO
3content be 60wt%.
Embodiment 4
Get 31.4g Ni (NO
3)
26H
2o, puts into the beaker of 500mL, adds the distilled water of 100mL, and then beaker is placed in the water-bath of 80 DEG C, stirring velocity is 400rpm.Get 34.3g La (NO
3)
36H
2o, is placed with in the beaker of 100mL distilled water, is stirred to whole dissolving.Then lanthanum nitrate hexahydrate is added drop-wise in nickel nitrate solution, dropping limit, limit is stirred.Get 40g citric acid, be placed with in the beaker of 100mL and be stirred to whole dissolving, after above-mentioned mixing solutions stirs 30 minutes, add citric acid solution slowly, dropping limit, limit is stirred.Stir after 5 hours, solution has dewatered and has become thick gel, is taken out by gel and puts in the loft drier of 110 DEG C, dried overnight.Then dried uhligite precursor is taken out, be placed in retort furnace, 400 DEG C are risen to from room temperature with the temperature rise rate of 3 DEG C/min, constant temperature calcining 3 hours, rise to 900 DEG C with the temperature rise rate of 10 DEG C/min again, constant temperature calcining 4 hours, obtain complex metal oxides oxygen carrier, wherein the mass content of NiO is 10wt%, LaNiO
3content be 90wt%.
Embodiment 5
Get 36.3g Ni (NO
3)
26H
2o, puts into the beaker of 500mL, adds the distilled water of 100mL, and then beaker is placed in the water-bath of 60 DEG C, stirring velocity is 400rpm.Get 34.3g La (NO
3)
36H
2o, is placed with in the beaker of 100mL distilled water, is stirred to whole dissolving.Then lanthanum nitrate hexahydrate is added drop-wise in nickel nitrate solution, dropping limit, limit is stirred.Get 40g citric acid, be placed with in the beaker of 100mL and be stirred to whole dissolving, after above-mentioned mixing solutions stirs 30 minutes, add citric acid solution slowly, dropping limit, limit is stirred.Stir after 5 hours, solution has dewatered and has become thick gel, is taken out by gel and puts in the loft drier of 110 DEG C, dried overnight.Then dried uhligite precursor is taken out, be placed in retort furnace, 400 DEG C are risen to from room temperature with the temperature rise rate of 3 DEG C/min, constant temperature calcining 3 hours, rise to 900 DEG C with the temperature rise rate of 10 DEG C/min again, constant temperature calcining 4 hours, obtain complex metal oxides oxygen carrier, wherein the mass content of NiO is 15wt%, LaNiO
3content be 85wt%.
Embodiment 6
Get 36.3g Ni (NO
3)
26H
2o, puts into the beaker of 500mL, adds the distilled water of 100mL, and then beaker is placed in the water-bath of 40 DEG C, stirring velocity is 400rpm.Get 34.3g La (NO
3)
36H
2o, is placed with in the beaker of 100mL distilled water, is stirred to whole dissolving.Then lanthanum nitrate hexahydrate is added drop-wise in nickel nitrate solution, dropping limit, limit is stirred.Get 40g citric acid, be placed with in the beaker of 100mL and be stirred to whole dissolving, after above-mentioned mixing solutions stirs 30 minutes, add citric acid solution slowly, dropping limit, limit is stirred.Stir after 5 hours, solution has dewatered and has become thick gel, is taken out by gel and puts in the loft drier of 110 DEG C, dried overnight.Then dried uhligite precursor is taken out, be placed in retort furnace, 400 DEG C are risen to from room temperature with the temperature rise rate of 3 DEG C/min, constant temperature calcining 3 hours, rise to 900 DEG C with the temperature rise rate of 10 DEG C/min again, constant temperature calcining 4 hours, obtain complex metal oxides oxygen carrier, wherein the mass content of NiO is 15wt%, LaNiO
3content be 85wt%.
Embodiment 7
Get 36.3g Ni (NO
3)
26H
2o, puts into the beaker of 500mL, adds the distilled water of 100mL, and then beaker is placed in the water-bath of 80 DEG C, stirring velocity is 400rpm.Get 34.3g La (NO
3)
36H
2o, is placed with in the beaker of 100mL distilled water, is stirred to whole dissolving.Then lanthanum nitrate hexahydrate is added drop-wise in nickel nitrate solution, dropping limit, limit is stirred.Get 40g citric acid, be placed with in the beaker of 100mL and be stirred to whole dissolving, after above-mentioned mixing solutions stirs 30 minutes, add citric acid solution slowly, dropping limit, limit is stirred.Stir after 5 hours, solution has dewatered and has become thick gel, is taken out by gel and puts in the loft drier of 110 DEG C, dried overnight.Then dried uhligite precursor is taken out, be placed in retort furnace, 400 DEG C are risen to from room temperature with the temperature rise rate of 3 DEG C/min, constant temperature calcining 3 hours, rise to 1000 DEG C with the temperature rise rate of 10 DEG C/min again, constant temperature calcining 4 hours, obtain complex metal oxides oxygen carrier, wherein the mass content of NiO is 15wt%, LaNiO
3content be 85wt%.
Embodiment 8
Adopted volume impregnation legal system for NiO/ LaNiO
3.
First LaNiO is prepared
3.Get 23gNi (NO
3)
26H
2o, puts into the beaker of 500mL, adds the distilled water of 100mL, and then beaker is placed in the water-bath of 80 DEG C, stirring velocity is 400rpm.Get 34.3g La (NO
3)
36H
2o, is placed with in the beaker of 100mL distilled water, is stirred to whole dissolving.Then lanthanum nitrate hexahydrate is added drop-wise in cobalt nitrate solution, dropping limit, limit is stirred.Get 40g citric acid, citric acid and metal ion total amount mol ratio are 1.2:1, and the beaker putting into 100mL is stirred to whole dissolving, after above-mentioned mixing solutions stirs 30 minutes, adds citric acid solution slowly, and dropping limit, limit is stirred.Stir after 5 hours, solution has dewatered and has become thick gel, is taken out by gel and puts in the loft drier of 110 DEG C, dried overnight.Then take out dried uhligite precursor, be placed in retort furnace, rise to 400 DEG C with the temperature rise rate of 3 DEG C/min from room temperature, constant temperature calcining 2 hours, rise to 800 DEG C with the temperature rise rate of 10 DEG C/min again, constant temperature calcining 3 hours, obtain complex metal oxides oxygen carrier.
Secondly, the above-mentioned LaNiO prepared of 12g is got
3be placed in the flask of Rotary Evaporators, temperature is set to 80
oc.Get 8.48g Ni (NO
3)
2﹒ 6H
2o, is placed in 100mL beaker, adds 50mL distilled water and dissolves.Then open vacuum pump, after exhausting vacuum, Ni solution is extracted in flask, adjustment rotating speed, start dry.After water evaporates is complete, taking-up is placed in 110 DEG C of loft drier spends the night, then roasting, rise to 400 DEG C with the temperature rise rate of 3 DEG C/min from room temperature, constant temperature calcining 2 hours, then rise to 800 DEG C with the temperature rise rate of 10 DEG C/min, constant temperature calcining 3 hours, obtain complex metal oxides oxygen carrier, wherein the mass content of NiO is 15wt%, LaNiO
3content be 85wt%.
Comparative example 1
Adopt conventional sol-gel method to prepare nickel oxide (load is on silicon oxide) particle, maturing temperature is with embodiment 1.
Embodiment 9
Catalyst performance evaluation prepared in above-described embodiment and comparative example is carried out as follows.Catalyst Evaluation Test carries out in continuous fixed bed reactor, gets catalyzer 3ml, with same order number quartz sand by volume 1:1 mix.Fuel gas is carbon monoxide (10 vol% CO, 90 vol% N
2), flow is 200ml/min, and temperature of reaction is 900 DEG C, and reaction pressure is normal pressure.Reduce after 5 minutes, switch to nitrogen, simultaneous temperature remains on 900 DEG C, keeps 20 minutes.Then inject water with syringe pump, flow is 20ml/h, and water is first vaporized, and then enters preheater, and the temperature of preheater remains on 160 DEG C, then enters reactor.React after 10 minutes, switch to air and continue oxidation 3min, then switch to nitrogen, simultaneous temperature remains unchanged.Pass into fuel gas again, reaction conditions is consistent with above-mentioned reduction reaction conditions.Adopt 6890 type gas-chromatography on-line analyses, 5A molecular sieve column and Porapak Q post, TCD detects.Evaluation results is in table 1.
The reactivity worth of table 1 catalyzer.
Catalyzer | CO transformation efficiency (%) a | H 2Output, (ml/g Ni) b |
Embodiment 1 | 99 | 199 |
Embodiment 2 | 98 | 187 |
Embodiment 3 | 95 | 173 |
Embodiment 4 | 97 | 168 |
Embodiment 5 | 96 | 192 |
Embodiment 6 | 95 | 187 |
Embodiment 7 | 94 | 175 |
Embodiment 8 | 87 | 146 |
Comparative example 1 | 69 | 89 |
acO transformation efficiency is the mean value of circulation 50 times.
bthe productive rate of hydrogen carries out calculating (water is excessive) based on Ni,
Namely every gram of Ni reductive water steam can generate the volume of hydrogen, is circulation 50
Secondary mean value.
Claims (2)
1. the application of oxygen carrier in recycle chemistry chain hydrogen production, oxygen carrier is by the LaNiO with perovskite structure
3complex metal oxides and nickel oxide composition, by the weighing scale of final oxygen carrier, have the LaNiO of perovskite structure in this oxygen carrier
3the content of complex metal oxides is 50% ~ 95%, the content of nickel oxide is 5% ~ 50%, oxygen carrier preparation method is as follows: with nickelous nitrate, lanthanum nitrate is presoma, with citric acid or ethylene glycol for complexing agent, wiring solution-forming mixing and stirring, then moisture evaporation is carried out, the colloidal sol of solution went from clear is transformed into the gel of thickness, finally by drying, roasting obtains described oxygen carrier, complexing agent and metal ion mol ratio are 1:1 ~ 3:1, the mol ratio of metal ion nickel and metal ion lanthanum is 1.1:1 ~ 3.5:1, preparation and stirred solution carry out at 50 ~ 80 DEG C, churning time is 4 ~ 6 hours, drying temperature is 80 ~ 150 DEG C, time of drying is 8 ~ 24 hours, roasting roasting 3 ~ 8 hours at 600 ~ 900 DEG C, the temperature of reaction of oxygen carrier in fuel is 600 ~ 1200 DEG C, the temperature of reaction of oxygen carrier in water vapor is 600 ~ 1200 DEG C.
2. according to application according to claim 1, it is characterized in that: oxygen carrier is spherical, particle size is 10 μm-2000 μm.
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甲烷部分氧化制合成气La-Ni-O系催化剂性能的研究;郭翠梨;《中国博士学位论文全文数据库 工程科技Ⅰ辑》;20090415(第4期);第20页第2.2.2节,第46页第4.2.2节 * |
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