CN1289820A

CN1289820A - Process for dearsenicating hydrocarbon oil

Info

Publication number: CN1289820A
Application number: CN 99119666
Authority: CN
Inventors: 冷冰; 余启炎; 顾申; 马志元; 刘菊安; 石翠; 阎立梅; 袁霞光
Original assignee: Sinopec Beijing Research Institute of Chemical Industry; China Petrochemical Corp
Current assignee: Sinopec Beijing Research Institute of Chemical Industry; China Petrochemical Corp
Priority date: 1999-09-24
Filing date: 1999-09-24
Publication date: 2001-04-04
Anticipated expiration: 2019-09-24
Also published as: CN1118540C

Abstract

本发明提供了一种脱砷吸附剂。该吸附剂是由活性组分和载体组成,所述的载体选自由活性氧化物(γ－Al₂O₃、β－Al₂O₃、η－Al₂O₃、θ－Al₂O₃)、二氧化钛、氧化硅－氧化铝或它们的混合物组成组中的至少一种或几种;所述的活性组分选自由铜(锌)氧(硫)化物、硫酸盐(氧化铜、氧化锌、硫化铜、硫化锌、硫酸铜、硫酸锌)或它们的混合物组成组的至少一种或几种,以吸附剂的总重量计,活性组分为1—20重量%余量为载体。本发明还提供了从烃油中脱除砷(胂)的方法。The invention provides an adsorbent for removing arsenic. The adsorbent is composed of an active component and a carrier, and the carrier is selected from active oxides (γ-Al ₂ O ₃ , β-Al ₂ O ₃ , η-Al ₂ O ₃ , θ-Al ₂ O ₃ ) , titanium dioxide, silica-alumina or mixtures thereof; the active components are selected from the group consisting of copper (zinc) oxide (sulfur) compounds, sulfates (copper oxide, zinc oxide, At least one or more of copper sulfide, zinc sulfide, copper sulfate, zinc sulfate) or their mixtures, based on the total weight of the adsorbent, the active component is 1-20% by weight and the balance is the carrier. The invention also provides a method for removing arsenic (arsine) from hydrocarbon oil.

Description

A kind of method that from hydrocarbon ils, removes arsenic

The present invention relates to a kind of method that removes arsenic.More particularly, the present invention relates to use the sorbent material of forming by active ingredient and carrier, from the hydrocarbon ils of sulfur-bearing and arsenic, remove the method for arsenic.

As everyone knows, the heavy metal arsenic that contains in hydrocarbon ils such as the petroleum naphtha produces many injurious effects to the deep processing of hydrocarbon ils.Process catalyst is poisoned, be deposited on the surface of processing unit and pipe fitting etc., cause coking, reduced output and economic benefit, when serious, even technological process can not be carried out.Therefore, the arsenic content in the stock oil there is strict regulation, for example, 20-2000ppb.In order to remove arsenic, people have carried out research chronically, have proposed various arsenic removing methods.

United States Patent (USP) 3782076,3789871,3542669 and 4849577 all relates to is not having to remove arsenic in the presence of the organosulfur.

The used sorbent material of arsenic removal comprises for example PbO/Al ₂O ₃, CuO/ γ-Al ₂O ₃, CuO/ZnO/ γ-Al ₂O ₃

United States Patent (USP) 4593148 discloses the method for removing arsine from the air-flow that contains arsine and hydrogen sulfide.This method is that described air-flow is contacted with the sorbent material of being made up of cupric oxide and zinc oxide.Described sorbent material is to be prepared by coprecipitation method or pickling process.

United States Patent (USP) 5169516 discloses a kind of method of removing arsenic from the liquid stream that contains arsenic and sulfide.This method is arsenic removal after the first desulfurization, and the used sorbent material of arsenic removal is not contain or the low γ-Al that contains ₂O ₃Cupric oxide or zinc oxide dearsenification sorbent material.

The inventor compares arsenic removal (arsine) method and the used sorbent material of prior art, at problems of the prior art, study chronically and test, found a kind of arsenic removal that not influenced by sulfide (arsine) sorbent material and arsenic removal (arsine) method.This method is with dearsenification sorbent material such as CuSO ₄/ Al ₂O ₃, the arsenic in the hydrocarbon oil crude material (arsine) is reduced to less than 10ppb from 300ppb.

Therefore, the purpose of this invention is to provide a kind of dearsenification (arsine) sorbent material, be used for removing the arsenic (arsine) of hydrocarbon ils logistics.

Another object of the present invention provides a kind of arsenic removal (arsine) method.

Dearsenification of the present invention (arsine) sorbent material is made up of active ingredient and carrier.Described active ingredient is selected from the oxygen (sulphur) of copper (zinc) and changes thing or vitriol, for example, and at least a in cupric oxide, zinc oxide, zinc sulphide, cupric sulfide, copper sulfate, zinc sulfate or its mixture.Described carrier is selected from activated alumina, and for example, it is selected from γ-Al ₂O ₃, β-Al ₂O ₃, η-Al ₂O ₃, θ-Al ₂O ₃Or at least a in a kind of, the titanium dioxide in its mixture, silicon-dioxide-aluminium sesquioxide or their mixture.Activated alumina can prepare with diaspore calcination under 400 ℃ of-800 ℃ of temperature.The specific surface area of activated alumina is 150-250m ²/ g, pore size distribution are 10-200A, and total pore volume is 0.4-1.0ml/g, crushing strength be greater than 0.2 newton/.

The preparation method of the carrier that dearsenification of the present invention (arsine) sorbent material is used with activated alumina add an amount of (about 10 weight %-are in the weight of activated alumina) nitric acid or hydrochloric acid, an amount of water (about 29 weight %-are in activated alumina weight) and an amount of pore-forming material and additive made thick, be shaped to strip or granular with method well known in the art, be generally φ 2mm-φ 5mm.Dry back in 120 ℃ 400-800 ℃ of calcination.

Dearsenification of the present invention (arsine) preparation of adsorbent method is by proportioning active ingredient to be made the aqueous solution, and an amount of carrier is immersed in the made solution, after 100-120 ℃ of drying, gets final product in the calcination in airflow of 400-800 ℃ temperature.The method of dipping is that those skilled in that art are known, available dry immersion, and also available soak law, also available spraying method is held on the carrier as long as active ingredient can be carried.Active ingredient is carried the amount that is held on the carrier and is generally 1-20 weight %, is preferably 5-15 weight %, 7-13 weight % more preferably, and surplus is a carrier.

Arsenic (arsine) capacity of dearsenification of the present invention (arsine) sorbent material is more than 0.8% (weight), and life cycle was at least 1 year.

The active evaluation test of dearsenification (arsine) sorbent material is to carry out in fixed-bed reactor.Its test conditions is:

Catalyzer loading amount 100ml (granular, φ 2-3mm)

The stock oil petroleum naphtha

Temperature 30-110 ℃ of dearsenification (arsine)

Adsorption bed working pressure normal pressure-3.0Mpa

Air speed 1-4h ^-1

Dearsenification of the present invention (arsine) sorbent material use for some time or by arsenic (arsine) saturated after, can regenerate.Its regeneration condition is:

Regeneration temperature 200-400 ℃

Resurgent gases nitrogen air speed 500-2000h ^-1The quality of used petroleum naphtha is as follows in the test:

Proportion 0.71-0.76

Boiling range ℃

Initial boiling point 46

50％ 99

90％ 129

Do 203

Arsenic (ppb) 300

Sulphur (mg/l) 132

Describe the present invention further below by embodiment, the present invention is more in depth understood with promotion.But the present invention is not subjected to the restriction of these embodiment.Those skilled in the art can make amendment or improve under the guide of spirit of the present invention the present invention, all belong to apparent.Propose in protection scope of the present invention appended claims book below.Embodiment 1

The preparing carriers I:

With the known coprecipitation method of crowd, be about to make titanium hydroxide in the ammonium hydroxide adding titanium tetrachloride, after the washing drying, under 500 ℃ of-600 ℃ of temperature, the roasting decomposition obtains titanium dioxide.Adding pore-forming material, binding agent carry out moulding, and obtaining specific surface area is 150-200m ²/ g, pore volume are the carrier (I type) of 0.5-0.7ml/g.

The preparing carriers II:

Make aluminium hydroxide with coprecipitation method.Add nitric acid or polyoxyethylene glycol or molecular weight and be 10000 stick, make ball or column.400 ℃ of-500 ℃ of temperature roastings, obtain specific surface 180-200m then ²/ g, pore volume are the carrier (II type) of 0.7-0.9ml/g.

The preparing carriers III:

With commercially available activated alumina or aluminium oxide-silicon oxide ball, through water vapor or add expanding agent and handle, obtain the carrier (III type) of institute's palpus.

Embodiment 2

Preparation of Catalyst I-pickling process

Take by weighing each 1000 gram of I type, II type and III type carrier, immerse 800ml, concentration is in the copper sulfate solution of 15 weight %, soak and dry after doing, dry back makes C-I type, C-II type and C-III type catalyzer in 400 ℃ of roastings under 120 ℃ of temperature.

Preparation of Catalyst II-spraying method

Adopt spraying method, make C-IV type, C-V type C-V I type catalyzer by the condition in the Preparation of Catalyst I.

Embodiment 3

The activity rating of catalyst test:

Evaluation test 1

Get any catalyzer 100ml (granular φ 2-3mm) of above-mentioned preparation, the fixed-bed reactor of the φ 20 * 1000mm that packs into.Under envrionment temperature and normal pressure, press 2.0h ^-1The air speed feeding contains arsenic 200ppb and sulfur-bearing is the petroleum naphtha of 134ppm, and its experimental result is as follows:

Time (hour) outlet arsenic (ppb)

40 1

88 6．5

160 6．9

208 8．5

256 8．8

Evaluation test 2

Use following dearsenification condition: pressure is 3.0h as 3.0Mpa, air speed ^-1With temperature be 50 ℃, 70 ℃, 90 ℃, ℃ 110, other is identical with evaluation test 1 to carry out dearsenification, its test-results is as follows:

Time (hour) outlet arsenic (ppb)

50℃ 70℃ 90℃ 110℃

42 7．3 5．7 1．2 ＜1

66 5．4 4．1 1．6 ＜1

90 10．2 4．8 1．4 ＜0．5

114 12 4．2 1．1 ＜1

138 8．9 3．5 1．3 ＜1

162 9．5 5．3 1．2 ＜1

234 10 4．4 2．0 ＜1

282 - 4．7 2．1 ＜1

306 - ＜1 1．7 ＜1

330 - 3．9 3．8 ＜1

Evaluation test 3

In temperature is that 70 ℃, pressure are that 3.0Mpa, air speed are 3h ^-1With petroleum naphtha to contain arsenic be 200ppb with the sulfur-bearing condition that to be 134ppm and other identical with evaluation test 1 under, carry out the dearsenification test.Measure sulphur content in the oil of reaction back simultaneously.Its test is as follows:

Time (hour) sulphur content (mg/l)

24 123

48 133

96 123

Embodiment 4 regeneration tests

After with the petroleum naphtha that contains arsenic 1000ppb catalyzer being quickened poisoning and deactivation, carry out manipulation of regeneration.

Get decaying catalyst 500ml, in the regenerating tube of packing into, with 600h ^-1Air speed feeds nitrogen.Under 350 ℃ of temperature, purge the organism in the sorbent material.After no longer including organism in the tail gas, under the constant condition of air speed, allocate the air of 1 volume % into, occur this moment heating up.Regulate air flow quantity, keep that temperature rise is the highest to be no more than 450 ℃.No longer heat up when increasing air capacity again, i.e. regeneration is finished.

Catalyzer after the regeneration is packed in the reactor, is that 50 ℃, pressure are 3.0h for normal, air speed in temperature ^-1Contain under the condition that arsenic is 200ppb with petroleum naphtha, carry out the dearsenification test.Its result is as follows:

Time (hour) outlet arsenic (ppb)

22 7．3

70 5．4

118 16．0

238 18．4

310 16．7

400 17．1

Embodiment 5

After will using 3200 hours, the catalyst segments of arsenic-removing rate 90% is measured the arsenic content on the different catalysts bed.

Catalyst bed arsenic content (weight %)

Inlet 0.9

The bed in 0.5

Outlet 0.1

Claims

1. A method for removing arsenic (arsine) from naphtha, the method is characterized in that naphtha is contacted with an adsorbent composed of an active component and a carrier, and the active component is selected from copper oxide, Zinc oxide, copper sulfide, or their mixtures, zinc sulfide, copper sulfate, zinc sulfate, or their mixtures form at least one or more of the group, and the carrier is selected from activated alumina, titanium dioxide, silicon dioxide- Al2O3 or their mixtures constitute at least one or more of the group, based on the total weight of the adsorbent, the active component is 1-20% by weight, and the balance is carrier.

2. The method according to claim 1, characterized in that said activated alumina is selected from γ-Al ₂ O ₃ , β-Al ₂ O ₃ , η-Al ₂ O ₃ , θ-Al ₂ O ₃ or their mixtures At least one or several of the group.

3. The method according to claim 1, characterized in that the surface area of the activated alumina is 150-250m ² /g, the effective pore diameter is 10-100A°, and the total pore volume is 0.4-1.0ml/g.

4. The method according to claim 1, characterized in that the adsorbent contains 5-15% by weight of the active component, and the rest is a carrier.

5. The method according to claim 1, characterized in that the active component of the adsorbent is copper sulfate and the carrier is γ-Al ₂ O ₃ .

6. The method according to claim 1, characterized in that the active components of the adsorbent are copper sulfate and copper sulfide, and the carrier is γ-Al ₂ O ₃ .

7. The method according to claim 1, characterized in that the active components of the adsorbent are copper oxide and zinc oxide, and the carrier is γ-Al ₂ O ₃ .

8. A method according to claim 1, characterized in that the adsorbent is prepared by impregnation.

9. A method according to claim 1, characterized in that the adsorbent is prepared by spraying.