Expander cycle

Expander rocket cycle. Expander rocket engine (closed cycle). Heat from the nozzle and combustion chamber powers the fuel and oxidizer pumps.

The expander cycle is a power cycle of a bipropellant rocket engine. In this cycle, the fuel is used to cool the engine's combustion chamber, picking up heat and changing phase. The heated, now gaseous, fuel then powers the engine's pumps and turbine before being injected into the combustion chamber and burned.

Because of the necessary phase change, the expander cycle is thrust limited by the square-cube rule. As the size of a bell-shaped nozzle increases with increasing thrust, the nozzle surface area (from which heat can be extracted to expand the fuel) increases as the square of the radius. However, the volume of fuel that must be heated increases as the cube of the radius. Thus there exists a maximum engine size of approximately 300 kN of thrust beyond which there is no longer enough nozzle area to heat enough fuel to drive the turbines and hence the fuel pumps. Higher thrust levels can be achieved using a bypass expander cycle where a portion of the fuel bypasses the turbine and or thrust chamber cooling passages and goes directly to the main chamber injector. Non-toroidal aerospike engines do not suffer from the same limitations because the linear shape of the engine is not subject to the square-cube law. As the width of the engine increases, both the volume of fuel to be heated and the available thermal energy increase linearly, allowing arbitrarily wide engines to be constructed. All expander cycle engines need to use a cryogenic fuel such as hydrogen, methane, or propane that easily reach their boiling points.

Some expander cycle engines may use a gas generator of some kind to start the turbine and run the engine until the heat input from the thrust chamber and nozzle skirt increases as the chamber pressure builds up.

In an open cycle, or "bleed" expander cycle, only some of the fuel is heated to drive the turbines, which is then vented to atmosphere to increase turbine efficiency. While this increases power output, the dumped fuel leads to a decrease in propellant efficiency (lower engine specific impulse). A closed cycle expander engine sends the turbine exhaust to the combustion chamber (see image at right.)

Some examples of an expander cycle engine are the Pratt & Whitney RL10 and RL60[1] and the Vinci engine for the future Ariane 5 ME.[2]

Expander bleed cycle (open cycle)

Expander bleed cycle. Expander open cycle (Also named coolant tap-off).

This operational cycle is a modification of the traditional expander cycle. In the bleed (or open) cycle, instead of routing heated propellant through the turbine and sending it back to be combusted, only a small portion of the propellant is heated and used to drive the turbine and is then bled off, being vented overboard without going through the combustion chamber. Bleeding off the turbine exhaust allows for a higher turbopump output by decreasing backpressure and maximizing the pressure drop through the turbine. Compared with a standard expander cycle, this leads to higher engine thrust at the cost of sacrificing some efficiency due to essentially wasting the bled propellant by not combusting it.

Advantages

The expander cycle has a number of advantages over other designs:

Some examples of an expander cycle engine are the Pratt & Whitney RL10 and RL60[1] and the Vinci engine for the future Ariane 5 ME.[3]

Usage

Expander cycle engines include the following:

Expander Bleed cycle engines have been used in:

Comparison of Expander cycle engines for upper stage

Specifications
  RL-10 Vinci YF-75D RD-0146 LE-5A LE-5B
Country of origin  United States  France  People's Republic of China  Russia  Japan  Japan
Cycle Expander Expander Expander Expander Expander bleed cycle,
nozzle expander
Expander bleed cycle,
chamber expander
Thrust, vac. 66.7 kN (15,000 lbf) 180 kN 88.26 kN 98.1 kN (22,054 lbf) 121.5 kN (12.4 tf) 137.2 kN (14 tf)
Mixture ratio 6.0 5 5
Nozzle ratio 40 80 130 110
Isp, vac. (s) 433 465 442 463 452 447
Chamber pressure (MPa) 2.35 6.1 7.74 3.98 3.58
LH2 TP (rpm) 125,000 51,000 52,000
LOX TP (rpm) 17,000 18,000
Length (m) 1.73 2.2~4.2 2.2 2.69 2.79
Dry weight (kg) 135 280 242 248 285

See also

References

External links

This article is issued from Wikipedia - version of the Saturday, March 12, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.