RU2296795C1 - Method of bt-301 synthetic oil recovery - Google Patents

Abstract

FIELD: chemical industry; methods of the synthetic oils recovery.

SUBSTANCE: the invention is pertaining to the field of chemical industry, in particular, to the method of ВТ-301 synthetic oil recovery and may be used for an oil recovery of the ВТ-301 synthetic oil applied in the heat-stressed gas-turbine engines. Substance: the method provides, that the oil is fed onto the filter with the porosity of 5-10 microns for separation from the mechanical impurities and then onto the filter with the microfiltration diaphragm with the porosity of 0.9-2 microns for filtration from the fine-dispersed gel-like particles. In the container used for the recovered synthetic oil they form the vacuum from 10⁴ Pa up to 10² Pa. The filters are arranged one above other and rest on the metallic plate with the holes and are disposed between the tanks for the dirty oil and recovered oil, connected among themselves hermetically. The technical result of the invention is provision of the high-degree of the synthetic oil purification, that enables its reusage in the heat-stressed gas-turbine engines.

EFFECT: the invention ensures provision of the high-degree of the synthetic oil purification, that enables its reusage in the heat-stressed gas-turbine engines.

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Description

The invention relates to the chemical industry and can be used for the regeneration of VT-301 oil used in heat-stressed gas turbine engines.

When conducting a patent search, according to the Discovery of Invention bulletins available from the enterprise from 1986 to 1991, the “Inventions” from 1992 to 1998, a synthetic BT-301 oil regeneration method, no analogues were found.

The diagram shows the elements of a synthetic oil recovery method VT-301.

The scheme contains a container for dirty oil 1, a container for regenerated oil 5, a filter for cleaning large (over 200 microns) mechanical impurities 2 with a porosity of 5-10 microns, a microfiltration membrane for cleaning fine mechanical and gel particles 3, a metal plate with holes 4, vacuum pump 6 (to create a low vacuum in the tank for regenerated oil 5).

Design features of heat-stressed gas-turbine engines require the presence of an 11 grade purity oil according to GOST 17216-2001.

Objective: to clean the VT-301 oil from mechanical and gel-like fine particles in order to reuse it in certain types of work.

The method of regenerating synthetic VT-301 oil includes: filtering from mechanical impurities (over 200 microns) through filter 2, filtering from fine mechanical and gel particles (from 5 to 200 microns) through a microfiltration membrane 3 with a normalized pore size of 0.9-2 microns .

Filters are located one above the other, rely on a metal plate with holes 4 (allows you to maintain the integrity of the filters). Filters are between the upper tank for dirty oil 1 and the tank for regenerated oil 5, which are tightly interconnected. A low vacuum of 10 ⁴ Pa to 10 ² Pa is created in the tank for regenerated oil 5 using a vacuum pump 6. For example: a portion of VT-301 synthetic oil, which has worked in the engine for 30 minutes, has mechanical and gel particles in an amount corresponding to 13 cleanliness class . The oil is placed in a container 1, and when creating a low vacuum in a container 5, the oil passes through filters 2 and 3, while mechanical and gel-like impurities remain on the filters. After regeneration, the oil has the required 11 class of purity and is reused in the operation of the engine. Oil having a significant amount of mechanical and gel fine impurities undergoes repeated regeneration with the obligatory replacement of filters with clean ones, until the required purity class is achieved.

Thus, this VT-301 oil regeneration method allows solving the problem of oil reuse for a certain type of engine operation.

Claims (1)

A method of regenerating synthetic VT-301 oil, comprising supplying dirty oil from a tank to a filter with a porosity of 5-10 μm for filtering from mechanical impurities, subsequent filtering from fine gel-like particles through a microfiltration membrane with a porosity of 0.9-2 μm when creating a vacuum in the tank for the recovered oil from 10 ⁴ to 10 ² Pa, with the filters are arranged one above the other, rest on a metal plate with holes and placed between tanks for dirty and recovered oil interconnected with tight battle.