RU2535518C1 - Oil system of power gas turbine unit - Google Patents

Abstract

FIELD: motors and pumps.

SUBSTANCE: oil system of power gas turbine unit (PGTU) relates to motor building, namely to PGTU oil systems, used in gas pumping and electric stations for driving of various units (pumps, gas and air compressors, electric generators etc.). The proposed PGTU is featured by the use of independent drainage vessels for each oily cavity of free turbine, connected to the individual scavenge pump, that allows to exclude in the oil scavenge system disbalance in operation of the pumps induced by moves of air flows from one oil cavity to another one through the integrated drainage cavity.

EFFECT: invention will allow to avoid the use of complementary extraction pump with electric drive, and mutual integration of pump mains of delivery pumps in the oil supply system will allow to improve the reliability of PGTU operation in case of failure of one of delivery pumps.

2 cl, 1 dwg

Description

The invention relates to the field of engine building, in particular, to an oil system of an energy gas turbine unit (EGTU), used at gas pumping and power plants to drive various units (pumps, gas and air compressors, electric generators).

A known oil system of a power gas turbine installation containing devices for supplying and pumping oil from oil cavities of the thrust bearings of the rotors of a turbocompressor and a free turbine. A device for pumping oil from the oil cavities of a free turbine includes a drainage tank in communication with the suction lines of pumping pumps driven by a turbocompressor, and a vent line through a normally open shut-off valve (see RF patent No. 2277175, IPC F02C 7/06, publ. May 27, 2006).

In the known oil system, a device for pumping oil from the oil cavities of the bearing supports of the rotor of a power turbine contains a single drainage tank for both oil cavities and an additional pump with electric drive, which is activated when it is full.

During the operation of the power plant, the air pressure in the oil cavities of the bearing supports of the rotor of the power turbine varies significantly due to different leaks in them through the air seals. As a result, air has the opportunity through a single drainage tank to flow from the oil cavity of the support bearing, where its pressure is higher, into the oil cavity of another support bearing, where its pressure is lower, which will disrupt the operation of pumping pumps operating on an oil-air emulsion and designed initially for a certain performance margin. Violation of the operation of the pumping pumps will lead to overflow of the drainage tank and the need to include an additional pumping pump with an electric drive, which reduces the reliability of the EGTU oil system.

The disconnection between the oil supply lines to the oil cavities of the bearing supports of the turbocompressor rotors and the power turbine does not allow, in the event of failure of one of the injection pumps, for example, the electric power turbine pressure pump, to ensure oil is supplied to it from another pressure pump driven by a turbocompressor, which also reduces the reliability of the oil system of the power plant.

The objective of the invention is to prevent disruption of the pumping pumps by eliminating the flow of air flows between the oil cavities of the supporting bearings of the rotors of the turbocompressor and a free turbine.

This problem is solved in that in the oil system of a power gas turbine installation containing devices for supplying and pumping oil from oil cavities of the supporting bearings of the rotors of a turbocompressor and a free turbine, the device for pumping oil from the oil cavities of a free turbine includes a drainage tank in communication with the suction lines pumping pumps driven by a turbocharger, and a vent line through a normally open shut-off valve, according to the invention, a drainage tank made in the form of two cavities isolated from each other, each of which is connected with the oil cavity of only one of the bearings of the free turbine and connected to one of the pumping pumps, is equipped with a separate vent line connected to the inlet of the shut-off valve, and pressure lines in the oil supply device The pressure pumps of the turbocharger and the free turbine are interconnected. In addition, individual vent lines for venting cavities of the drainage tank are equipped with nozzles and connected in parallel to a single shut-off valve.

The use of autonomous drainage tanks for each oil cavity of the bearing support of the rotor of a free turbine allows virtually eliminating the flow of air flows from one oil cavity to another, since air leakage through the venting lines can be neglected (the passage section of the venting channels of the drainage tank is two orders of magnitude smaller than the passage section of the suction lines of the pumping out pumps). EFFECT: invention prevents unbalancing in the operation of free turbine pumping pumps and eliminates overflow of the drainage tank, which will make it possible to abandon the use of an additional electric pumping pump in the device for pumping oil from the oil cavities of a free turbine.

The combination of the pressure lines of the injection pumps of the turbocompressor and the free turbine will eliminate the failure of the power plant in the event of failure of any of the injection pumps (power turbine or turbocompressor), as it allows oil supply to the turbocompressor and the free turbine, albeit with a reduced level of oil supply pressure (in limits).

The EGTU oil system includes a consumable oil tank 1, oil cavities of the bearing supports of the turbocompressor rotors and a free turbine, respectively 2, 3 and 4. On the drive box 5 with the drive from the turbocompressor rotor there are installed: a pump 6, a pump 7 and two pump 8, 9, the entrances to which are connected to the lower part of the cavities 10 and 11 of the drainage tank 12. The oil cavities 3 and 4 of the free turbine through the suction lines 13 and 14 communicate with the upper part of the cavities 10 and 11 of the drainage tank 12. The cavities 10, 11 have an individual The venting lines 15 and 16, respectively, are equipped with nozzles 17 and 18. The venting lines 15 and 16 at the output are combined into a single line 19, which is connected to the input of a normally open controlled shut-off valve 20. The EGTU oil system also has a second charge pump 21 with an electric drive . Pressure lines 22 and 23 of the discharge pumps 7 and 21 are combined and communicated through line 24 with the control cavity of the shut-off valve 20.

On a command to start the EGTU, the pressure pumps 7 and 21 are simultaneously put into operation. The productivity of the pressure pump 7 grows gradually - as the turbocharger rotor spins up, and the pressure pump 21 with an electric drive switches on instantly and basically provides oil supply to the unit in this mode. As the rotors of the turbocharger and the free turbine spin up, the charge pump 21 can be turned off and the oil supply to the installation will be provided only by the charge pump 7 driven by the turbocompressor rotor, but when stopped, the EGTU can be turned on again because the free turbine run-out is greater than the run-out turbocharger, and it is impossible to leave the bearing supports of a free turbine without lubrication while the rotor of the free turbine continues to rotate (under the action of inertia of the drive unit).

When the pressure pumps 7 and 21 are operating, oil flows through the pressure lines 22 and 23 to the nozzles of the oil cavities 2, 3 and 4, and along the line 24 into the control cavity of the shut-off valve 20, which closes, blocking the access of atmospheric air in the cavities 10 and 11 of the drainage tanks 12.

Used oil from the oil cavities 3, 4 of the free turbine through the suction lines 13 and 14 through isolated from each other closed cavities 10 and 11 is fed to the inlet of the pumping pumps 8 and 9, which transfer it to the consumable oil tank 1 for reuse. From the oil cavities 2 of the turbocharger, the used oil is transported to the consumable oil tank 1 by a suction pump 6.

The presence of venting lines 15, 16 of two nozzles 17 and 18, taking into account their low throughput, eliminates the flow of air flows between the cavities 10, 11 of the drainage tank 12, which ensures reliable operation of the pumping pumps 8, 9.

When EGTU stops, the oil pressure at the outlet of the discharge pump 7 and then 21 decreases, therefore, in the control cavity of the shut-off valve 20, which opens, communicating the cavities 10 and 11 with the atmosphere and ensuring that the remaining oil is drained from the oil cavities 3, 4 power turbines that are removed from the drainage tank 12 through the drain valves during subsequent maintenance of EGTU.

The implementation of the invention will improve the reliability of the EGTU oil system and the installation as a whole.

Claims (2)

1. The oil system of an energy gas turbine installation, comprising devices for supplying and pumping oil from oil cavities of the thrust bearings of the rotors of a turbocompressor and a free turbine, the device for pumping oil from the oil cavities of a free turbine includes a drain tank connected to the suction lines of pumping pumps driven by turbocharger, and the vent line through a normally open shut-off valve, characterized in that the drainage tank is made in the form of two insulated x cavities from each other, each of which is connected to the oil cavity of only one of the bearing bearings of a free turbine and is connected to one of the evacuation pumps, is equipped with a separate vent line connected to the inlet of the shut-off valve, and in the oil supply device the pressure lines of the turbocharger discharge pumps and free turbines are interconnected. 2. The oil system of an energy gas turbine installation according to claim 1, characterized in that the individual vent lines for venting the cavities of the drainage tank are equipped with nozzles and connected in parallel to a single shut-off valve.

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