Steamly S2-S/Systems

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SECTION 2. SYSTEMS

1 Helicopter

1.1 General

The Shergood Steamly S2-S is a single-engine steam-turbine powered helicopter. It employs a closed-loop steam system consisting of a boiler, a steam turbine, a condenser and a water reservoir. A fuel oil burner in the boiler provides the heat to produce steam which is then directed into the turbine through the throttle valve. Steam exiting the turbine is passed through a condenser with twin engine powered cooling fans.

1.2 Gross Weight

The maximum gross weight is 2,100 pounds.

1.3 Main Instrument Panel

S2s-main-panel-labeled.png

Figure 1: Main instrument panel
1. Tail-Number plate 2. Low Fuel Warning Light 3. Fuel Indicator 4. HOBBS Time
5. Compass Card 6. Clock 7. Low Boiler Pressure Warning Light 8. Low RPM Warning Light
9. Boiler Pressure Differential Indicator 10. Turbine Pressure Indicator 11. Engine/Rotor RPM Indicator 12. Attitude Indicator
13. Vertical Speed Indicator 14. Altimeter 15.Airspeed Indicator 16. Turn and Bank Indicator

1.4 Mid Instrument Panel

1. Boiler Temp./Water Level/Fuel Pressure Indicators
2. Boiler Pressure Indicator
3. Amps/Volts Indicator
4. Fuel Flow Control
5. Intercom (RP only)
6. Deathray Main Power
7. Radio
8. Transponder
9. Governor

S2s-mid-panel-labeled.png

Figure 2: Mid instrument panel

1.5 Switch Panel

Figure 3: Switch panel

A switch panel is located at the bottom of the instrument panel and contains the majority of the switches and breakers in the aircraft. Left to right the switches are:

  • Ignitor - Key switch that turns on the ignitors for the burner. Requires that electrical power be active as well.
  • Batt. (Master) - Main electrical power from the battery.
  • Dynamo (Master) - Main electrical power from the dynamo. The dynamo is powered when the engine RPM is at least 50%.
  • Aux Fuel Pump - Provides fuel pressure to the burner via an electrically driven pump
  • Feed Pump - Pumps water from the reservoir to the boiler.
  • Inst. Lights - Provides light for the cabin from two lights mounted on the back wall.
  • Nav. Lights - Powers the three navigation lights, right on the left, blue-green on the right and white on the tail.

1.6 Magnetic Compass

Figure 4: Magnetic Compass
Figure 5: Beacon
Figure 6: Rotor Brake

A magnetic compass (Figure 4) is mounted on top of the main instrument panel. Note that the magnetic compass is only accurate in straight and level flight and is subject to the following types of error:

  • Oscillation - Turbulence and motion of the aircraft will cause the compass reading to oscillate. The more steady the aircraft is held in a level attitude, the more accurate the reading will be.
  • Deviation - Magnetic fields generated by the aircraft itself can affect the compass reading. A compass card (Figure 1 (#5)) on the main panel provides corrections from indicated headings to actual headings.
  • Turning Error - Magnetic dip causes the compass to produce erroneous readings while in a turn on certain headings. These errors are most pronounced near North and South headings. While close to a North heading, the compass heading shown will tend to undershoot the actual heading, and while close to a South heading the heading shown will tend to overshoot the actual heading. When on an East or West heading, this error will be negligible. You can use the acronym UNOS (Undershoot North, Overshoot South) to remember direction of the error.

1.7 Beacon

A flashing beacon is mounted on the belly of the aircraft. The beacon is activated through a switch (Figure 5) mounted under the pilot seat.

1.8 Rotor Brake

A rotor brake lever (Figure 6) is mounted under the pilot seat. The rotor brake is on when the lever is in the up position.

2 Rotor and Power Train System

The rotor configuration of this helicopter consists of a single main lifting rotor system and an anti-torque tail rotor system. Both systems are driven by the engine through the transmission system and are controlled by the flight control system.

2.1 Main Rotor System

The main rotor system consists of the main rotor hub and three main rotor blades. Each should be inspected separately during the pre-flight inspection. The main rotor is controlled through a swash plate and control linkages connected to the collective and cyclic controls in the cockpit.

2.2 Tail Rotor System

The tail rotor is mounted on the right side of the vertical stabilizer. It acts to counteract torque from the main rotor and provide yaw control of the aircraft in a hover, and coordination for turns at cruise speed. The tail rotor is controlled through anti-torque pedals in the cockpit that alter the pitch of the blades thus increasing or decreasing the tail-rotor thrust.

2.3 Main Transmission

Figure 7: Main Transmission
1) Primary Drive Shaft, 2) Bevel Gear, 3) Centrifugal Clutch, 4) Sprag Clutch, 5) Tail Rotor Drive Shaft, 6) Main Rotor Reduction Gear

The main transmission (Figure 7) translates power from the engine to the rotor system. Rotational power is supplied through the main drive shaft (#1) from the steam turbine. A bevel gear (#2) translates the horizontal rotation from the main drive shaft to a vertical input shaft to the transmission. The transmission includes a centrifugal clutch (#3) and a sprag clutch (#4), an additional bevel tap gear (#5) for the tail rotor drive shaft, and finally a reduction gear (#6) to reduce the RPM from engine to the RPM for the main rotor.

2.3.1 Centrifugal Clutch

The centrifugal clutch (Figure 7, element #3) serves to decouple the rotor system from the engine during startup. It consists of four weighted balls mounted on hinges around a ring with friction pads attached to each weight through a lever. As the engine RPM increases, centrifugal force will pull the balls outward. When the centrifugal force is strong enough, the friction pads will contact the middle vertical drive shaft transferring the power from the engine.

2.3.2 Sprag (Freewheeling) Clutch

A sprag clutch (Figure 7, element #4) connects the middle vertical drive shaft to the upper vertical drive shaft. It consists of lower section with four spring-loaded teeth driven by the middle vertical drive shaft that interact with a ratchet gear driving the upper vertical drive shaft. This arrangement allows the main rotor to "freewheel" in the event power from the engine is lost.

3 Landing Gear

The S2-S has a fixed skid-type landing gear system with left and right skids mounted on shock absorbing pivots.

4 Engine and Related Systems

Figure 8: S2-S Engine

The S2-S is powered by a 200 HP steam turbine engine with a closed-loop system (Figure 8). A boiler provides steam pressure which is feed to a steam turbine through a throttle valve. Steam from the turbine passes through a condenser to a water reservoir, which is then pumped back to the boiler via a feed pump. Each of the components are described in further detail in the following sections.

4.1 Engine Components

Figure 9: Fuel Cutoff
4.1.1 Boiler

The main source of steam for the S2-S is a boiler is mounted in the rear of the engine compartment. The boiler consists of three sections, a firebox, a smokebox and the main boiler compartment. The firebox takes up the portion of the boiler on the right side of the aircraft and contains a burner fed by a fuel-oil line, and an ignitor to begin combustion at start-up. The smokebox on the left side of the aircraft collects the hot gasses from burner and channels them to the smokestack. A set of tubes passing through the main boiler chamber connects the firebox with the smokebox. It is important that the tubes remain submerged in water while the boiler is operating. The water level should never be allowed to fall below 90% capacity while operating.

Under normal operation, the pressure in the boiler chamber should be maintained between 300 and 400 psi. This pressure acts as an energy reservoir which can be directed to act on the turbine through a throttle valve. If the boiler pressure is allowed to fall bellow 300 psi, then there will be insufficient pressure to produce full power which can result in loss of rotor RPM when high power is demanded of the engine. Excessive boiler pressure, on the other hand, can lead to failure of the boiler pressure vessel and subsequent loss of the aircraft.

4.1.1.1 Burner
Figure 10: Burner

The burner (Figure 10) is located on the right side of the aircraft and can be accessed for inspection through a door on the side of the boiler. The burner is the primary source of heat for the boiler. A fuel flow lever in the cockpit controls the flow of fuel to the burner, and thus the rate at which heat is added to the system. An ignitor is used to start the flame for start up. While once the burner has started, the ignitor is no longer needed to maintain the flames, it is recommended that the ignitor be left on to facilitate reignition in the event the flame is extinguished.

WARNING: Never introduce fuel to the burner with the ignitor disengaged. The resulting fuel build-up can result in an explosion once an ignition source is later introduced.

4.1.2 Steam Turbine

A toroidal steam turbine is mounted in front of the boiler. The turbine has an throttle valve regulated input port on the top, and a steam exhaust port connecting to the condenser on the bottom. A horizontal drive shaft extends from the center of the turbine toward the front of the helicopter.

4.1.3 Condenser

Steam from the turbine is passed through a condenser, cooled by two engine-driven fans.

4.1.4 Water Reservoir

The water reservoir collects water after it has passed through the condenser. The water reservoir includes the following elements:

  • A electric feed pump to return water to the boiler so as to maintain the proper water level in the boiler.
  • A sightglass on the left side of the aircraft to show the current water level in the reservoir.
  • A filler cap to refill the water in the reservoir (click to refill).

4.2 Engine Instruments

Gauge Description
S2s-rpm.png RPM - A two needle gauge showing the speed of the engine (long needle marked "E") and the speed of the rotor system (short needle marked "R").
S2s-turbine-press.png Turbine Pressure - The steam pressure at the inlet to the turbine. This gauge represents the amount of power being produced by the engine at operating RPM.
S2s-boiler-press.png Boiler Pressure - Pressure inside the boiler. A green band indicates the normal operating range for boiler pressure.
S2s-boiler-press-diff.png Boiler Press. Diff. - Rate of change of boiler pressure in hundreds of psi/minute. The orange band indicates increasing pressure while the blue band indicates decreasing pressure.


S2s-three-gauge.png Multi-Gauge - Three part gauge showing the boiler temperature on top, the water level in the boiler on the lower left, and the fuel pressure on the lower right.

4.3 Cockpit Engine Controls

4.3.1 Fuel Flow
Figure 11: Fuel Flow

A fuel flow lever (Figure 11) mounted on the mid console is used to regulate the flow of fuel to the burner. Increasing the fuel flow will increase the temperature of the firebox and thus the rate of heat being transferred to the boiler. During flight, fuel flow should be adjusted as necessary to keep the boiler pressure between 300 and 400 psi. Once the boiler pressure is near the desired level, the boiler pressure differential gauge can be used to fine tune the amount of fuel needed to maintain pressure.

The fuel flow must be adjusted in response to change in the throttle (and thus collective) setting. As the throttle is increased, a higher fuel flow will be required to maintain sufficient boiler pressure. Conversely, as throttle is decreased, the fuel flow must be decreased to compensate for the lower power demand.

IMPORTANT: It is critical the fuel flow be reduced and adjusted after landing to prevent overpressure and potential rupture of the boiler vessel.

To operate the fuel flow lever, you can:

  • Click on the lever to activate the overlay, then click on the overlay. The overlay contains a main scale in which click on the scale moves the fuel flow to that position. In addition, a small "trim" scale to the right of the main scale can be used to make small up or down tweaks to the setting.
  • Click on the fuel flow setting in the "fuel" section of the HUD.
  • Use the chat command "ff n" where n is a fuel flow setting in percent. For example, to set the fuel flow to 60%, you can use the command:
ff 60
4.3.2 Throttle
4.3.3 Steam Whistle
Figure 12: Steam Whistle Control

A steam whistle that can be operated via a cable and pulley system is mounted on top of the boiler. A handle (Figure 12) on the floor of the cockpit is used to activate the steam whistle through a cable and pulley system. The whistle will operated when the handle is in the up position. The whistle can be used as an audible signal to nearby personal on the ground, or to assist in reliving excess pressure in the boiler.

When active, steam from the boiler is allowed to escape through the whistle. Extended use of the whistle will reduce pressure in the boiler over time, unless fuel flow is increased at the burner. For this reason, its use in flight is discouraged when pressure is below 300 psi. Conversely, opening the whistle in addition to reducing fuel flow can be used to more quickly reduce boiler pressure when the 400 psi limit has been exceeded.

The whistle is operated by clicking or using the chat command:

s whistle
4.3.4 Fuel Cutoff

A red fuel cut-off lever (Figure 9) is mounted under the pilot seat. Fuel flow to the burner is on when the lever is in the horizontal position.

4.4 External Engine/Boiler Ports

4.4.1 Vent Valve
Figure 13: Vent Valve

A vent valve (Figure 13) is located on the of the boiler vessel. This valve is used during startup to vent air from the boiler chamber to ensure that the chamber contains only steam during operation. Failure to vent the air from the boiler before operation will increase the temperature needed to achieve operating pressure and reduce the efficiency of the boiler.

4.4.2 Drain Valve

A drain valve is located on the underside of the boiler. The drain valve can be used to periodically drain the water from the boiler. This should be done at least once every 10 flights to eliminate mineral build-up in the water. Failure to periodically drain water can result in reduced performance and corrosion to engine parts.

5 Fuel System

6 Electrical System

7 Flight Controls

8 Lighting