DE1545260C3 - Process for the regeneration of used oils - Google Patents

Description

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The invention relates to a method for regenerating used engine oils or containing engine oils Industrial waste oils.

The term "waste oil" refers to used engine and industrial lubricating oils, their can no longer correspond to the original provision.

It is known that the waste oil collection and regeneration of waste oil in all countries, but mainly in the countries that do not have their own petroleum base, i.e. require an import, carried out systematically will. ■ "> · *

The known processes for regenerating used oils are based on treating the used oils with Sulfuric acid and fuller's earth or on treatment by solvent extraction. There will be too both methods used to clean one and the same waste oil. The purpose of these known methods is to extract all modified lubricating oil components and impurities from the waste oil and in this way the unchanged parts of the primary lubricating oil in pure form to win. The disadvantage of these known methods is that they are not economical, because they work with great losses, especially in the case of the engine oil component of the used oil forming the starting material should be obtained in a quality that corresponds to that of the corresponds to primary lubricating oil. In such cases the loss often reaches 60%.

The purpose of the invention is to eliminate the disadvantages of the known methods and a To offer a regeneration process that enables the modified components to be refined the engine oil components and other lubricating oil components of the waste oil are practically unchanged Regain amount.

With the help of the invention, products can be manufactured from waste oils, the quality of which is better than that of the primary lubricating oils. Accordingly, the invention provides those skilled in the art The prevailing view of the area is weakened, according to which the properties of the regenerated Lubricating oil cannot exceed those of the primary lubricating oil.

The invention is a process for the regeneration of waste motor oils or industrial waste oils containing motor oils, according to which the waste oil is pre-cleaned with the aid of coagulants and / or vacuum distillation and then under a pressure of 15 to 50 atm, expediently 20 to 40 atm, at a temperature of 280 to 380 ° C., expediently 320 to 360 ° C., with a space velocity of 0.5 to 2.0 liters / liter · hour, expediently 0.5 to 1.0 liter / liter · hour, with a gas-liquid ratio 10 to 120 NmVm ³ , preferably 20 to 80 Nm ³ / m ³ , is subjected to catalytic hydrogenation in the presence of a refining catalyst and the raffinate obtained is optionally fractionated.

In the present invention, the catalytic hydrogenation can preferably be carried out under a pressure of 20 to 40 atm be performed; accordingly, the hydrogen-rich product gases of the catalytic Gasoline reforming with its own pressure of 20 to 40 atm can be used very advantageously. Pure hydrogen gas or synthesis gas can also be used advantageously. The inventive Technology can serve well even if the waste engine oil also contains gas oil.

A particular advantage of the method according to the invention is that, in contrast to

the multi-stage conventional regeneration processes consisting of two steps, namely pre-cleaning and hydrogenation, and a higher yield with much lower manufacturing costs secures, especially in favor of the most valuable regenerated lubricating oil, the engine lubricating oil.

As a catalyst, it is expedient to use an aluminum oxide carrier, expediently - / - aluminum oxide carrier, applied nickel and molybdenum oxides can be used. The catalyst appropriately contains also other metal oxides, e.g. B. also iron oxide and silicon dioxide. The nickel and molybdenum oxides are expediently used in a ratio of 4 to 12 to 6 to 20. The following composition of the catalyst proved to be particularly advantageous:

NOK

Parts by weight
4 to 5

MoO ₃ 15 to 17

SiO ₂ 0 to 5

preferably 0 to 2

Fe ₂ O ₃ O to 15

preferably 5 to 10

It is useful to sulfide the catalyst before use, which is from the point of view of sustained activity is very beneficial from a perspective. It was also found that the activity of the The catalyst is favorably influenced if its activation before use in the hydrogenation reactor is carried out. The essence of the activating treatment is that over the catalyst under atmospheric pressure or under pressure for 4 to 12 hours at a temperature of a hydrogen-containing gas or oil is passed above 200 ° C, which is at least 0.1 percent by weight contains bound sulfur. Other known activating treatments can also be performed will.

With the aid of the process according to the invention, raffinates are obtained which have a satisfactory Viscosity, a satisfactory viscosity index,) freezing point and flash point, an acceptable one Have a color and a good smell and the oxidation stability of which is better than that of the conventional methods produced raffinates. Another advantage of the process is that it does not require any new equipment in the commonly used lubricating oil hydrogenation or gas oil desulfurization plants can be used. Another advantage is that it is used as a raw material for regeneration Mixed collection lubricating oils can be used.

The process according to the invention is explained in more detail using the examples below.

example 1

Percent by volume of hydrogen-containing synthesis gas is hydrogenated in the presence of a catalyst. The catalyst contains 4.5 percent by weight of nickel oxide, 16 percent by weight of molybdenum oxide, 2 percent by weight of silicon dioxide and 7 percent by weight of iron oxide on a 70.5 percent by weight of y-aluminum oxide support. Before use, the catalyst was treated in the hydrogenation reactor at 200 ° C in a hydrogen-containing gas stream and then at 350 ° C with a space velocity of 1.0 liter / liter hour, with a gas-liquid ratio of 0.5 Nm ³ / Liters, activated under a pressure of 40 atm with a gas oil containing 2 percent by weight of bound sulfur.

The hydrogenated product is fractionated in vacuo. Made from 100 percent by weight parts of the original Waste oil will receive the following products:

Weight percent

Regenerated engine oil 48.2

Refined gas oil and regenerated

Industrial lubricating oil distillates 32.5

Pre-cleaning losses 17.5

Losses in hydrogenation and distillation

lation 1.8

Total 100.0

The hydrogenated engine oil has the following properties:

Weight percent Conradson number, weight percent .. 0.09

Viscosity at 50 ° C, cSt 66.8

Viscosity ratio (V., / Vj) 1.35

Conradson Difference (C ₂ -C ₁ ) 1.04

The same starting material is treated with 5% by weight of concentrated sulfuric acid, after which the 82.5 percent by weight of prepurified waste oil obtained using conventional technology be worked up, d. H. the pre-refined material is vacuum distilled, the fraction containing the engine oils is extracted with furfural and the raffinate obtained in this way and the machine oils containing distillates are treated with sulfuric acid and fuller's earth. Be that way receive the following products:

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A waste oil containing motor oils and industrial waste oils with a water content of 7 percent by weight is treated with 5 percent by weight concentrated sulfuric acid. This way it becomes 82.5 percent by weight Receive pre-cleaned waste oil. This oil is at 360 ° C with a space velocity of 0.5 liter / liter hour, under a pressure of 40 atm, with 25 volume percent nitrogen and 75 Weight percent

Gas oil and industrial lubricating oils 38.9

Regenerated engine oil 26.4

Fuel oil 8.5

Pre-cleaning losses 17.5

Loss on regeneration 8.7

Total 100.0

Properties of the regenerated engine oil thus obtained:

Weight percent

Viscosity index 79

Conradson number, percent by weight. 0.15

Viscosity at 50 ° C, cSt 59.8

Viscosity ratio (V / Vj) 1.5

Conradson difference (C ₂ -C ₁ ) 1.4

From the above information it is clear that with the help of the method according to the invention

regenerated engine oils can be obtained in a significantly higher quantity and in a better quality can than with traditional methods. The products obtained according to the invention from lower boiling points have considerably better properties.

Example 2

The procedure is as described in Example 1, with the difference that the hydrogenation is carried out at 320 ° C., with a space velocity of 0.5 liters / liter • hour, under a pressure of 35 atm. is carried out with a gas-liquid ratio of 0.05 Nm ³ / liter with a reforming gas which contains 90 percent by volume hydrogen and 10 percent by volume light hydrocarbons. Before use, the catalyst was pretreated in the hydrogenation reactor at 210 ° C. in a synthesis gas stream and then sulfided at 360 ° C. under a pressure of 20 atm in a synthesis gas stream containing _{2 percent by weight of CS 2.} In this way the following products are obtained:

Weight percent

Regenerated engine oil 54.1

Refined gas oil and regenerated

Industrial lubricating oil distillates .... 26.9

Loss of pre-cleaning 17.5

Loss on hydrogenation and distillation 1.5

Total 100.0

Properties of the regenerated engine oil obtained:

Weight percent

Viscosity index 75

Conradson number, percent by weight. 0.19

Viscosity at 50 ° C, cSt 72.6

Viscosity ratio (V ^ V ₁ ) .. 1.38

Conradson Difference (C ₁ -C ₁ ) 1.08

Example 3

Proceed as described in Example 1, with the difference that after that with sulfuric acid carried out pre-cleaning, the pre-cleaned used oil is distilled in a vacuum. This will make the Components boiling below 420 ° C removed. The bottom product containing the engine oil components the distillation is worked up according to the method described in Example 1. In this Way, the following products are made:

Weight percent

Regenerated engine oil 58.2

Gas oil and industrial lubricating oil distillates 22.8

Pre-cleaning losses 17.5

Losses in hydrogenation and distillation 1.5

Total 100.0

The hydraulic engineered engine oil has the following Features on:

Weight percent

Viscosity index 80

. Conradsoa number, percent by weight. 0.15

• V viscosity at 50 ° C, cSt 53.66

Viscosity ratio (V ₂ ZV ₁ ) 1.54

Conradson difference (C ₂ -C ₁ ) 0.86

Example4

It is, as described in Example 3 of NIIT the difference that the bottom product of the distillation at a temperature of 350 ⁰ C, at a space velocity of 0.25 liter / liter · hour, with a gas-liquid ratio of ³ 0,12Nm / Liter, under a pressure of 20 atm, with 75 percent by volume of hydrogen and 25 percent by volume of nitrogen-containing synthesis gas is hydrogenated. In this way the following products are obtained:

Weight percent

Regenerated engine oil 57.8

Gas oil and industrial lubricating oil distillates 22.8

Loss with pre-cleaning 17.5

Loss in hydrogenation and Destil ^a5 lation 1.9

Total 100.0

The regenerated engine oil thus obtained has the following properties:

Weight percent

Viscosity index 85

Conradson number, percent by weight. 0.18

Viscosity at 50 ° C, cSt 46.24

Viscosity ratio (V, ZVj) 1.69

Conradson Difference (C ₂ -C ₁ ) 1.08

Example 5

One proceeds as described in Example 1, with the difference that the hydrogenation in one Temperature of 350 ° C, with a space velocity of 0.8 liters / liter ■ hour, with a gas-liquid ratio of 0.1 N / V liters, under a pressure of 50 atm, with 75 percent by volume Synthesis gas containing hydrogen and 25 percent by volume of nitrogen is carried out. To this Way, the following products are obtained:

Weight percent

Regenerated engine oil 53.8

Refined gas oil and regenerated

Industrial lubricating oil distillates 26.6

Pre-cleaning losses 17.5

Losses in hydrogenation and distillation 2.1

Total 100.0

The regenerated engine oil obtained in this way has the following properties:

Weight percent

Viscosity Index 81

Conradson number, weight percent. 0.10

Viscosity at 50 "C, cSt 68.31

Viscosity ratio (V ₁ ZV ₁ ) 1.28

Conradson diflerence (C ", -C,) 1.06

Claims (6)

Patent claims: 1. A method for regenerating waste motor oils or industrial waste oils containing motor oils, characterized in that the waste oil is pre-cleaned with the aid of coagulants and / or by vacuum distillation and then under a pressure of 15 to 50 atm, at a temperature of 280 to 380 ° C, with a space velocity of 0.5 to 2.0 liters / liter · hour, with a gas-liquid ratio of 10 to 120 Nm ³ / m ³ , is subjected to catalytic hydrogenation in the presence of a refining catalyst and the raffinate obtained is optionally fractionated. 2. A method for regenerating waste motor oils or industrial waste oils containing motor oils according to claim 1, characterized in that the waste oil is pre-cleaned with the aid of coagulants and / or by vacuum distillation under a pressure of 20 to 40 atm, at a temperature of 320 to 360 ° C, is subjected to catalytic hydrogenation at a space velocity of 0.5 to 1.0 liter / liter hour, with a gas-liquid ratio of 20 to 80 Nm ³ / m ³ , in the presence of a refining catalyst and the raffinate obtained is optionally fractionated. 3. The method according to claims 1 and 2, characterized in that a catalyst consisting of nickel oxide and molybdenum trioxide, with a NiO: MoO ₃ ratio of 4 to 12 to 6 to 20 on an aluminum oxide carrier is used. 4. The method according to claims 1 to 3, characterized in that a catalyst consisting of 4 to 5 parts by weight NiO, 15 to 17 parts by weight MoO ₃ , 0 to 5 parts by weight, preferably 0 to 2 parts by weight SiO ₂ and 0 to 15 parts by weight, preferably 5 to 10 _{parts by weight of Fe 2} O ₃ on an aluminum oxide support, preferably on a 7-Al ₂ O _{3 support} , is used. 5. Process according to claims 1 to 4, characterized in that the hydrogenation carried out with the hydrogen-rich product gases of the catalytic gasoline reforming will. 6. Process according to claims 1 to 5, characterized in that a catalyst is used is, which in the hydrogenation reactor 4 to 12 hours, at a temperature of over 200 ° C in an at least 0.1 percent by weight bound sulfur-containing gas oil stream or hydrogen-rich gas stream has been treated is.