Two-stage compressor widens the application range, Features and benefi ts, Why centrifugal compressors surge – Trane Centrifugal Water Chillers CVGF User Manual

Two-Stage Compressor Widens the Application Range

Why Centrifugal Compressors Surge

Centrifugal compressors produce their pressure differential

(head) by converting the kinetic energy of the gas leaving

the impeller into static pressure. The velocity of this gas is

the result of two components:

• The radial velocity component V

r

, which is directly

proportional to the refrigerant gas fl ow Q.

• The tangential velocity component V

t

,which is a function of

both impeller diameter D and the rotational speed rpm.

The length of the resultant vector V is proportional to the

kinetic energy available for conversion to static pressure

in the volute. Consequently, for a given compressor, V

t

is

fi xed and V

r

varies with the cooling load. With the chiller

unloading, the pressure differential between evaporator and

condenser decreases. The compressor matches the new load and the lower “head” by closing the

inlet guide vanes.

This reduces the gas fl ow it draws in and modifi es its direction. Component V

r

decreases

accordingly, the vector diagram shifts and at some point, the balance of forces breaks down.

As pressurized gas rushes backwards through the impeller, the pressure in the gas passages

falls, allowing the compressor to restore the balance of forces. If the process repeats itself, the

compressor is said to surge.

Two-Stage Compressors Surge Less and Later

To produce the same head as a single-stage compressor, two-stage machines use two small

diameter impellers. Component V

t

is the same as on each stage, though V

r

is the same as on a

single-stage compressor. This results in a better balance of forces at low loads and produces a

machine with a wider unloading capability.

In Trane centrifugal chillers, gas prerotation vanes ahead of the compression stage improve impeller

aerodynamic effi ciency, resulting in smoother unloading and reducing power consumption.

The curves show that two-stage compressors surge less and later than single-stage machines.

Intersection point B, when the load line meets the surge area, corresponds to a higher part load

for the single-stage compressor than would be the case with a two-stage compressor. Two stage

machines, therefore, have a wider range of applications.

1 - Load Line

2 - Surge Line

3 - A

4 - B

5 - 40%

6 - 90° Vanes

7 - 100%

8 - Compressor Head

9 - Refrigerant Gas Flow

1 - V

r

= f (Q)

2 - V

t

= f (D, RPM)

3 - V = Resultant

4 - rpm

5 - D

6 - Q

Typical single-stage compressor
performance curve

1 - Load Line

2 - Surge Line

3 - A

4 - B

5 - 20%

6 - 90°

7 - 80°

8 - 70° Vanes

9 - 100%

10 - Compressor Head

11 - Refrigerant Gas Flow

Typical two-stage compressor
performance curve

10

Features and Benefi ts

CTV-PRC001-E4