RU2584224C1 - Centrifugal compressor - Google Patents

Abstract

FIELD: compressor building.

SUBSTANCE: invention relates to compressor building industry. Centrifugal compressor comprises stator with vaneless diffusers, installed coaxially to it rotor on radial and axial bearings with controlled rigidity, made in form of electromagnetic bearings, radial and axial rotor position sensors, end seals. Axial support with controlled rigidity includes at least two axial electromagnets, one of which is intended for operation in zone of gas-dynamically stable operating conditions, and rest are intended for inclusion into action when compressor enters in zone of rotating failure preceding surging, and off at leaving from rotating failure zone preceding surging.

EFFECT: invention allows to enhance economic efficiency and safety of operation of centrifugal compressor.

4 cl, 2 dwg, 1 tbl

Description

The invention relates to the field of compressor engineering, mainly centrifugal direction.

A centrifugal compressor is known from the prior art, comprising a stator with bladeless diffusers, a rotor mounted inside it on electromagnetic bearings having radial and axial bearings, radial and axial rotor position sensors, end seals (see, for example, A.Z. Shaikhutdinov, etc. “Creation of the NTs-16M Ural supercharger with an electromagnetic suspension and dry seals.” Collection of reports of the St. Petersburg State Polytechnic University “Proceedings of the Ninth International Symposium, 2003, pp. 160-165).

Comparative bench tests on model gas (air) of compressors with the same flow part, but with different supports - electromagnetic and oil, showed the clear advantages of the compressor on electromagnetic supports, including the stability of operation at low flow rates (in the pre-surge zone).

The damping properties of electromagnetic bearings, even with fixed stiffness of bearings and an analog control system, can significantly (by 15-20%) increase the area of stable operation of compressors in the field of low productivity. That is, the electromagnetic suspension of the rotor is capable of playing the role of a device to prevent the self-oscillating process of gas outflow in the flow part (surge), which is dangerous for the compressor.

An essential feature that reliably characterizes the beginning of the region of gas-dynamic instability of the compression process (rotating stall) is an increase in the amplitude of the oscillations of the axial position of the rotor (an increase in the value of axial vibration displacement).

However, the disadvantages of this device include:

- poor stability in the low-cost area;

- limited damping of rotor vibrations during compressor operation due to a fixed value of the stiffness of the electromagnets controlled by an analog control system;

- the axial force, perceived by the persistent electromagnet, is limited by the calculated (excluding surge phenomena) value of the axial forces acting on the rotor in the zone of gas-dynamic safe operating modes of the compressor.

At the same time, for many centrifugal compressors (in particular, having a gentle curve of the degree of pressure increase on productivity in the left part of the characteristic and small values of the degree of pressure increase π = 1.15-1.6), a positive slope of the characteristic does not appear until until the flow rate changes significantly. The extent of the surge-free zone of such compressors can be extended.

There are ways to increase the safe operation area of a centrifugal compressor due to the use of electromagnetic bearings with a bearing value that takes into account both static and dynamic effects on the rotor that occur during compression, as well as through optimization of the characteristics of dynamic corrective devices in the feedback loops of the control system of these bearings.

The closest analogue in technical essence is a centrifugal compressor (NTs-12 / 56-1.44) driven by a gas turbine engine and an elastic coupling, containing a stator with bezlopatochnye diffusers, a rotor mounted on it with electromagnetic bearings having radial and axial bearings of adjustable stiffness and radial and axial position sensors of the rotor, end seals (see Y.Z. Guzelbaev, A.L. Khavkin “Features of carrying out surge tests and adjusting the anti-surge protection system of centrifugal compressors with electric bearings ". In the collection of reports" Proceedings of the XIV International Scientific and Technical Conference on Compressor Technology. Kazan, 2007, Volume 2, pp. 179-192).

The NTs-12 / 56-1.44 compressor has a greater margin of bearing capacity both in radial and axial bearings, which allowed expanding the range of stable operation of the compressor in the low-flow area from 210 m ³ / min to 170 m ³ / min, those. by 20%. This fact is reflected in table 1.

It should be noted that both compressors NTs-12 / 56-1.44 and NTs-16 / 76-1.44, tested in real conditions, contained a unified design of electromagnetic bearings with the same bearing capacity.

The disadvantages of this device are the limited damping of rotor vibrations during compressor operation, the low range of compressor stable operation with reduced costs, and the presence of a fixed (calculated) value of the axial force that can be perceived.

The objective of the invention is to increase the economic efficiency and operational safety of a centrifugal compressor by expanding the range of stable operation and reducing energy costs when working in the field of low costs by using the damping properties of electromagnetic bearings and eliminating the need for bypass (bypassing) gas.

The technical result of the invention is to provide damping of the oscillation of the rotor in the field of low consumption of compressed gas, expanding the range of stable operation of the compressor while reducing consumption.

The technical result is achieved due to the fact that the centrifugal compressor contains a stator with bladeless diffusers, a rotor coaxially mounted to it on radial and axial bearings of adjustable stiffness, made in the form of electromagnetic bearings, radial and axial position sensors of the rotor, end seals, while the axial bearing of adjustable stiffness includes at least two axial electromagnets, one of which is designed for compressor operation in the zone of gas-dynamic stable operation modes, and the rest The others are designed to be activated when the compressor enters the zone of the rotating stall preceding the surge, and turned off when leaving the zone of the rotating stall preceding the surging.

In addition, the axial support has a housing connected to the stator.

In addition, the axial support can be made in the form of a separate unit mounted on the part of the rotor protruding beyond the stator.

In addition, electromagnetic bearings have a bearing capacity that is at least two times higher than the calculated values of the radial and axial forces acting on the rotor under gasdynamically stable operating conditions.

The invention is illustrated by drawings, where in FIG. 1 shows a General view of the proposed centrifugal compressor; in FIG. 2 shows a structural diagram of a centrifugal compressor with an external axial support.

The centrifugal compressor contains a stator 1 with bladeless diffusers, inside of which a rotor 2 is coaxially mounted to it. Rotor 2 is mounted on radial 3 and axial 4 bearings with adjustable stiffness, made in the form of electromagnetic bearings.

The compressor also contains end seals 5 mounted on the rotor 2, as well as sensors 6 of the radial and axial position of the rotor 2. The radial bearings 3 and the axial support 4 have a stiffness control to change the damping properties. Supports 3 and 4 are designed and manufactured for loads at least twice the values of the radial and axial forces acting on the rotor 2 in the nominal compression mode. The feasibility study of the advantages of a centrifugal compressor with electromagnetic bearings of increased bearing capacity was carried out on the example of the compressor NTs-12 / 56-1.44, in which the zone of stable operation in the field of low productivity expanded from 210 m ³ / min to 170 m ³ / min.

The radial electromagnetic bearing (radial bearing 3) has its own rotor and stator parts (the rotor and stator of the radial electromagnetic bearing, not shown). The rotor of the radial bearing (rotor part) is mounted (mounted) on the rotor 2 and is equipped with ferromagnetic plates that are held by magnetic fields created by electromagnets placed on the stator of the radial bearing (stator part), which is mounted in the cover of the compression housing. The rotor levitates in the center without touching the stator. Various inductive sensors monitor the position of the rotor. These sensors detect any deviation from the normal position and give signals that regulate the currents of the electromagnets, which bring the rotor to its normal initial position.

Axial electromagnetic bearing (axial support 4)

The axial support 4 (see Fig. 1) is located on the part of the rotor 2 that extends beyond the stator 1 and has a housing 7 connected to the stator 1 mainly by threaded connections (the connection can also be carried out in any other possible way).

Axial support 4 consists of several axial electromagnets of increased carrying capacity, one of which is designed to operate the compressor in the zone of gas-dynamic conditions (right branch of the characteristic), the rest are activated when the compressor enters the zone of rotating stall preceding the surge. Methods of obtaining a signal about the origin of a rotating stall are known (see, for example, the article cited for the closest analogue). When the compressor returns to the zone of gasdynamically stable modes, only one axial electromagnet remains in operation, the rest are switched off. Since most of the time the compressor is operated in a zone of stable conditions, such a load distribution on axial electromagnets allows reducing energy costs.

The centrifugal compressor (see Fig. 2) may have an external axial support 4, made in the form of a separate unit mounted on the part of the rotor 2, protruding outside the stator 1, while the housing 7 of the support 4 is not connected to the stator 1. In this case, the axial The support 4 also has several axial electromagnets of increased carrying capacity (located outside the compression housing), operating in the same way as described above. Removing the axial support 4 into a separate housing 7, not connected with the stator 1, will simplify the explosion protection system of the axial electromagnet, improve the conditions of maintenance and cooling of the support.

An axial bearing works in the same way as a radial bearing. An additional disk (disks, not shown) is installed (mounted) on the rotor 2, which is the rotor part of the axial electromagnetic bearing (rotor 2 with thrust disks) and which is placed perpendicular to the rotation axes and opposite the electromagnets, which are the stator part of the axial bearing and which provide two-way attraction.

As a rule, the working set of compressor magnetic bearings consists of two radial bearings, one axial (thrust) bearing, a set of safety bearings (usually rolling) and a control unit for the compressor rotor 2 magnetic bearing system.

In the design of the proposed compressor, up to two to three nodes of axial bearings can be present, including in a remote unit (Fig. 2). A larger number is undesirable, since an increase in nodes of more than three will greatly complicate the design and, by increasing the length of the rotor 2, will reduce the dynamic stability of the system.

When operating a centrifugal compressor, radial 3 and axial 4 bearings, which have an increased bearing capacity, allow damping of the rotor 2 in the region of low flow rates of compressed gas, as a result of which a rotating stall does not lead to a self-oscillating process characteristic of surging. The higher the margin in the bearing capacity of electromagnetic supports, the wider the range of stable operation of the compressor with reduced consumption.

When the compressor is operating in the zone of low flow rates and maximum compression, phenomena of gas-dynamic instability (rotating stall) and pre-surge phenomena are observed, which are accompanied by oscillations of the rotor 2 in the axial direction. The control unit of the magnetic support system allows the early stages to determine the approximation of the zone of unstable operation and, issuing commands for the amount of force holding the rotor 2 in a balanced state of levitation, move the rotor 2 within the allowable clearances, changing the design clearances and the axial forces pattern in the presence of one axial bearings, and subsequently, with deeper non-stationary modes, connect additional axial bearings to increase the magnitude of the axial magnet force.

The ability to achieve a positive effect when using the invention is proved in the literature specified in the prototype.

When using traditional oil bearings or electromagnetic bearings with insufficient bearing capacity to ensure stable operation of the NTs-12 / 56-1.44 compressor, at a flow rate to the discharge manifold of less than surge value, it is necessary to bypass (bypass) a part of the gas from the discharge line to the suction line. That is, at a flow rate of 170 m ³ / min to the network, the compressor needs additional power ΔN for compressing 40 m ³ / min of gas. These costs can be calculated by the formula:

The gas density ρ _n at the inlet to the compressor is:

The specific work of compression l _to in the compressor is calculated:

where the degree of pressure increase is

For compressor NTs-12 / 56-1,44:

Taking into account formulas (2), (3), (4) and (1), the calculated value of the additional power consumption is ΔN = 1270 kW. At the same time, electromagnetic bearings, which ensure stable operation of the compressor at a flow rate of 170 m ³ / min without the use of gas bypass, consume less than 10 kW.

Comparison of the obtained values of the power spent on compression of additional volumes of gas and ensuring the operability of electromagnetic bearings clearly speaks in favor of the latter as a means of ensuring stable and safe operation of the compressor in the low-flow zone.

Claims (4)

1. A centrifugal compressor comprising a stator with a bladeless diffuser, a rotor coaxially mounted to it on radial and axial bearings of adjustable stiffness, made in the form of electromagnetic bearings, radial and axial position sensors of the rotor, end seals, characterized in that the axial bearing of adjustable stiffness includes at least at least two axial electromagnets, one of which is designed for compressor operation in the zone of gas-dynamic stable operation modes, and the rest are intended for inclusion in the action when the compressor enters the zone of the rotating stall preceding the surge, and off when leaving the zone of the rotating stall preceding the surging. 2. The compressor according to claim 1, characterized in that the axial support has a housing connected to the stator. 3. The compressor according to claim 1, characterized in that the axial support is made in the form of a separate unit mounted on a part of the rotor protruding beyond the stator. 4. The compressor according to claim 1, characterized in that the electromagnetic bearings have a bearing capacity of at least two times the calculated values of the radial and axial forces acting on the rotor under gasdynamically stable operating conditions.

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