Compressors pump gas for a wide variety of applications each of which has its own flow resistance which the compressor has to meet to keep the gas flowing. A map shows the pumping characteristics for the complete range of flows and pressure requirements for its application. The map may be produced by driving the compressor with an electric motor with the flow resistance selected artificially using a variable area throttle valve. The compressor may also be mapped if it is part of a gas generator with a valve at the turbine exit. Campbell shows a
General Electric J79 compressor mapped in this way.
Dimensional analysis Compressor performance changes, day to day, with changes in the ambient pressure and temperature. Woolenweber shows the change in performance of a
turbocharger compressor when the inlet temperature varies between 70 and 100 °F. In the case of aircraft compressors, inlet pressure and temperature also change with altitude and airspeed. The presentation of different performance for every combination of inlet temperature and pressure would be unmanageable but it is possible to collapse it all onto a single map, which is applicable to a wide range of inlet conditions, using
dimensional analysis. In dimensional analysis individual quantities such as rotor speed, mass flow and delivery pressure are each grouped with other relevant quantities in such a way that the groups have no dimensions but still have a physical meaning. For example rotor speed N, inlet temperature T, compressor diameter D and gas properties \gamma and R are grouped together as dimensionless ND/\sqrt{\gamma RT} which is equivalent to the blade mach number. Parameter groups which are used as the basis for gas turbine engine compressor maps are total-pressure ratio (
Pexit/
Pinlet), w\sqrt{\gamma RT}/{AP}, ND/\sqrt{\gamma RT} and efficiency. ND/\sqrt{\gamma RT}, for example, is simplified below while still being representative of mach number. Maps for other applications use head or discharge pressure and volume flow. For a particular compressor and gas the flow and speed groups are simplified, by deleting the terms which are constant for a particular compressor and application, namely compressor dimensions and gas properties D, A, R and . They are named pseudo-non-dimensional parameters w\sqrt{T}/{P} and N/\sqrt{T}. A final step is to give the pseudo-non-dimensional parameters standard units for mass flow and speed and more recognizable numerical values by applying pressure and temperature ratio correction factors, also derived as part of the dimensional analysis. The corrected parameters are w\sqrt{\theta}/\delta and N/\sqrt{\theta}. They have the same units as the original observed values and are corrected to agreed standard conditions, the
International Standard Atmosphere at sea level (ISA SL). Alternatively they may be shown relative to the design value where the design value is specified as either 100% or 1.0. The fuel burned in a gas turbine engine sets the compressor running line and also has to be used in "non-dimensional" form to show its effect on engine operation. It is used as a ratio with combustor pressure when shown on a compressor map. Corrected fuel flow is shown as w_\text{fuel} = w/\sqrt{\theta}\,\delta. Although both air and fuel are flows of fluid, their non-dimensional parameters are different, w\sqrt{\theta}/\delta and w/\sqrt{\theta}\,\delta, because non-dimensional airflow is a form of fluid Mach number, while fuel is flow of an incompressible energy source. The dimensions of airflow are M/t, and those of fuel-flow are ML2/t3, where M, L and t are mass, length and time. Fuel flow is also shown on a compressor map, but in the form of its effect, i.e. turbine inlet temperature. This effect is shown, again non-dimensionally, as the ratio of turbine inlet temperature to compressor inlet temperature, and known as engine temperature ratio. Grandcoing shows the constant temperature lines crossed as a helicopter compressor goes from no-load to full-load with increasing fuel flow.
Correcting observed or measured values to standard day conditions From the equality of the flow parameters on two different days (w\sqrt{T}/{P})day 1= (w\sqrt{T}/{P})day 2, measured values on one day can be corrected to those that would be measured on a standard day so, wcorr = = w\sqrt{T/519}/(P/14.7) where w, T, P are measured values and 519 degR and 14.7lb/sq in are the standard day temperature and pressure. The temperature and pressure correction factors are \theta and \delta, so wcorr = w\sqrt{\theta}/{\delta} For speed the corrected value is Ncorr = N/\sqrt{\theta}
Example: An engine is running at 100% speed and 107 lb of air is entering the compressor every second, and the day conditions are 14.5 psia and 30 deg F (490 deg R). On a standard day the airflow would be = 107\sqrt{490/519}/(14.5/14.7) which is 105.2 lb/sec. The speed would be = 100/\sqrt{490/519} which is 103%. These corrected values are what would appear on the compressor map for this particular engine. This example shows that a compressor runs aerodynamically faster on a 'cold' day and would be slower on a 'hot' day. Since the 'day' conditions are those at entry to the compressor an extremely 'hot' day is produced artificially by the ram temperature rise at high Mach numbers. The aerodynamic speed is low enough, despite the engine running at its 100% rated mechanical speed, to get into the rotating stall region on the map so an engine operating at these Mach numbers needs the appropriate features. The
General Electric J93 had variable inlet guide vanes and stators. The
Pratt & Whitney J58 had inter-stage bleed from the compressor and 2-position inlet guide vanes. The
Tumansky R-15 had pre-compressor cooling to reduce the air temperature and avoid low corrected speeds.
Kinematic similarity The basis for using corrected parameters on the map is mach number
kinematic similarity. Corrected flow and speed define mach numbers through the compressor and flow angles onto the blades using
velocity triangles. Velocity triangles allow flows to be transferred between different reference frames. In this case gas velocity and circumferential blade velocity in a stationary frame is converted to velocity in a rotating frame (rotor) passage. Losses in blade and vane rows depend primarily on incidence angles and mach number. A particular operating point on the map determines the mach numbers and flow angles everywhere in the compressor.
Flight at high Mach numbers A historical example, the
Pratt & Whitney J58, illustrates the significance of using corrected values. Rotating stall occurs at low corrected speeds so occurs during starting and also above idle. It may be relieved by opening a bleed valve to increase airflow. At very high flight speeds the compressor will return to this low corrected speed area so the same operating point occurs at low
rotational speed on the ground and maximum rotational speed at mach 3 at high altitude. The stalling, low efficiency, blade vibration and failure that plagued low corrected speeds on the ground has returned at 100% rotor
rpm at mach 3. The same operating point on the map has the same axial and peripheral mach numbers, same velocity triangles, same efficiency despite the actual rotor speed and compressor inlet temperature being 4750 RPM/60 °F on the ground and 7,000 RPM/over 600 °F at Mach 3. The same corrected operating point required the same solution to prevent stalling and increase efficiency which was to
bleed air from the 4th compressor stage.
Operating boundaries The compressor has operating boundaries at the flow extremes for a particular speed which are caused by different phenomena. The steepness of the high flow part of a constant speed line is due to the effects of compressibility. The position of the other end of the line is located by blade or passage
flow separation. There is a well-defined, low-flow boundary marked on the map as a stall or surge line, at which blade stall occurs due to positive incidence separation. Not marked as such on maps for turbochargers and gas turbine engines is a more gradually approached, high-flow boundary at which passages choke when the gas velocity reaches the speed of sound. This boundary is identified for industrial compressors as overload, choke, sonic or stonewall. The approach to this flow limit is indicated by the speed lines becoming more vertical. Other areas of the map are regions where fluctuating vane stalling may interact with blade structural modes leading to failure, ie rotating stall causing
metal fatigue. ==Operating ranges for different applications==