Single Versus Dual Recycle System Dynamics of High Pressure Ratio, Low Inertia Centrifugal Compressor Stations

Compression systems are designed and operated in a manner to eliminate or minimize the potential for surge, which is a dynamic instability that is very detrimental to the integrity of the compressor unit. Compressor surge can occur when compressors are subjected to rapid transients such as those occurring following an emergency shutdown (ESD) or a power failure, which in turn, requires fast reaction. To prevent this from occurring, compressor stations are designed with single or dual recycle systems with recycle valves, which are required to open upon ESD. There has been extensive debate and confusion as to whether a single recycle or a dual recycle system is required and the circumstances and the conditions under which one system or the other must be used. This paper discusses this crucial design issue in detail and highlights the parameters affecting the decision to employ either system, particularly for high pressure ratio, low inertia compressors. Parameters such as gas volume capacitance (V) in the recycle path, compressor power train inertia, compressor performance characteristics, the recycle valve coefficient (Cv), prestroke and stroke time, and check valve dynamic characteristic are crucial in determining the conditions for dynamic instabilities. A simple analytical methodology based on the perturbation theory is developed that provides a first-cut analysis to determine if a single recycle system is adequate for a given compression system. The concept of an inertia number is then introduced with a threshold value that determines which recycle system to use. Techniques to circumvent compressor surge following ESD are discussed and their respective effectiveness are highlighted including when and if a delay in the fuel cutoff will be effective. An example of a case study with actual field data of a high pressure ratio centrifugal compressor employed in a natural gas compressor station is presented to illustrate the fundamental concept of single versus dual recycle systems.

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Single vs. Dual Recycle System Requirements in the Design of High Pressure Ratio, Low Inertia Centrifugal Compressor Stations

Volume 4: Cycle Innovations; Fans and Blowers; Industrial and Cogeneration; Manufacturing Materials and Metallurgy; Marine; Oil and Gas Applications ◽

10.1115/gt2011-45002 ◽

2011 ◽

Cited By ~ 2

Author(s):

K. K. Botros

Keyword(s):

High Pressure ◽

Centrifugal Compressor ◽

Dynamic Instability ◽

Pressure Ratio ◽

Check Valve ◽

Threshold Value ◽

Analytical Methodology ◽

High Pressure Ratio ◽

Compressor Surge ◽

Rapid Transients

Compression systems are designed and operated in a manner to eliminate or minimize the potential for surge, which is a dynamic instability that is very detrimental to the integrity of the compressor unit. Compressor surge can occur when compressors are subjected to rapid transients such as those occurring following an emergency shutdown (ESD) or a power failure, which in turn, requires fast reaction. To prevent this from occurring, compressor stations are designed with single or dual recycle systems with recycle valves, which are required to open upon ESD. There has been extensive debate and confusion as to whether a single recycle or a dual recycle system is required and the circumstances and the conditions under which one system or the other must be used. This paper discusses this crucial design issue in detail and highlights the parameters affecting the decision to employ either system, particularly for high pressure ratio, low inertia compressors. Parameters such as gas volume capacitance (V) in the recycle path, compressor power train inertia, compressor performance characteristics, the recycle valve coefficient (Cv), pre-stroke and stroke time, and check valve dynamic characteristic are crucial in determining the conditions for dynamic instabilities. A simple analytical methodology based on the perturbation theory is developed that provides a first-cut analysis to determine if a single recycle system is adequate for a given compression system. The concept of an inertia number is then introduced with a threshold value that determines which recycle system to use. Techniques to circumvent compressor surge following ESD are discussed and their respective effectiveness are highlighted including when and if a delay in the fuel cut-off will be effective. An example of a Case study with actual field data of a high pressure ratio centrifugal compressor employed in a natural gas compressor station is presented to illustrate the fundamental concept of single vs. dual recycle systems.

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Application of Three Methods in Determining the Effectiveness of Surge Protection Systems in Gas Compressor Stations

Volume 1: Upstream Pipelines; Project Management; Design and Construction; Environment; Facilities Integrity Management; Operations and Maintenance; Pipeline Automation and Measurement ◽

10.1115/ipc2012-90618 ◽

2012 ◽

Cited By ~ 1

Author(s):

K. K. Botros ◽

D. Bakker

Keyword(s):

Dynamic Instability ◽

Pressure Ratio ◽

High Volume ◽

High Pressure Ratio ◽

Compressor Surge ◽

Fast Transients ◽

Complementary Nature ◽

Discharge Gas ◽

Surge Protection ◽

Rapid Transients

Compression Systems are designed and operated in a manner to eliminate or minimize the potential for surge, which is a dynamic instability that is very detrimental to the integrity of the unit. Compressor surge can occur when compressors are subjected to rapid transients such as one following emergency shutdown (ESD) or power failure. To prevent this from occurring, compressor stations are designed with recycle systems and special types of recycle valves, which are required to open upon ESD. These recycle valves must have specific characteristics to cope with such fast transients and protect the compressor for undergoing surge. This paper describes three methods for determining the effectiveness of any specific recycle system and recycle valve characteristics. These three methods are: i) the concept of the Inertia number, ii) a simplified method based on system impedance, and iii) full dynamic simulation of the compression system. These three methods are applied to a high pressure ratio (up to 3.5) natural gas compressor station involving very high volume of piping and equipment contained within the recycle loop. There is a heat exchanger to utilize the heat of compression to heat the condensate separated downstream in the discharge scrubber, two large aerial coolers to cool the high temperature discharge gas from the compressor, and the discharge scrubber itself. This equipment and associated large volume capacitance contained therein presented a significant challenge and demand on the surge suppression system in all aspects of operation; particularly during ESD. Results are presented from all three methods which show the consistency and complementary nature of these methods.

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Development of a Very High Pressure Ratio Single Stage Centrifugal Compressor

International Review on Modelling and Simulations (IREMOS) ◽

10.15866/iremos.v8i3.6020 ◽

2015 ◽

Vol 8 (3) ◽

pp. 347

Author(s):

Valeriu Dragan ◽

Ion Malael ◽

Bogdan Gherman

Keyword(s):

High Pressure ◽

Centrifugal Compressor ◽

Pressure Ratio ◽

Single Stage ◽

High Pressure Ratio ◽

Very High

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Effect of Recirculation Device With Counter Swirl Vane on Performance of High Pressure Ratio Centrifugal Compressor

Volume 7: Turbomachinery, Parts A, B, and C ◽

10.1115/gt2011-45360 ◽

2011 ◽

Cited By ~ 1

Author(s):

Hideaki Tamaki

Keyword(s):

High Pressure ◽

Mach Number ◽

Flow Rate ◽

Centrifugal Compressor ◽

Pressure Ratio ◽

Negative Slope ◽

Tip Leakage Flow ◽

Recirculation Flow ◽

Operating Range ◽

High Pressure Ratio

Centrifugal compressors used for turbochargers need to achieve a wide operating range. The author has developed a high pressure ratio centrifugal compressor with pressure ratio 5.7 for a marine use turbocharger. In order to enhance operating range, two different types of recirculation devices were applied. One is a conventional recirculation device. The other is a new one. The conventional recirculation device consists of an upstream slot, bleed slot and the annular cavity which connects both slots. The new recirculation device has vanes installed in the cavity. These vanes were designed to provide recirculation flow with negative preswirl at the impeller inlet, a swirl counterwise to the impeller rotational direction. The benefits of the application of both of the recirculation devices were ensured. The new device in particular, shifted surge line to a lower flow rate compared to the conventional device. This paper discusses how the new recirculation device affects the flow field in the above transonic centrifugal compressor by using steady 3-D calculations. Since the conventional recirculation device injects the flow with positive preswirl at the impeller inlet, the major difference between the conventional and new recirculation device is the direction of preswirl that the recirculation flow brings to the impeller inlet. This study focuses on two effects which preswirl of the recirculation flow will generate. (1) Additional work transfer from impeller to fluid. (2) Increase or decrease of relative Mach number. Negative preswirl increases work transfer from the impeller to fluid as the flow rate reduces. It increases negative slope on pressure ratio characteristics. Hence the recirculation flow with negative preswirl will contribute to stability of the compressor. Negative preswirl also increases the relative Mach number at the impeller inlet. It moves shock downstream compared to the conventional recirculation device. It leads to the suppression of the extension of blockage due to the interaction of shock with tip leakage flow.

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