LOVE THAT EGGBEATER
Posted: Sat Jan 28, 2017 3:41 pm
Earlier, someone asked if I had been the author of a little treatise on flying helicopters. I've dusted it off and repeat it below. It started out as a one page reflection on rotary wing flight "Author Unknown". I added to it...
LOVE THAT EGGBEATER
(Many of us belong to an exclusive club – those who understand the terms lead, lag, and flapback. For those who are convinced that helicopters are just collections of stuff going the same way the same day, I submit the following which was based on a Bell 47…)
PART 1
The helicopter is an amazing assortment of nuts, bolts, rotors, push-pull rods, irreversibles, longitudinal collective differential quadrants, swash plates, wobble plates, gimble rings, cuff links, trunion assemblies and other gadgets too humorous to mention. All of these are welded, riveted, bolted or sewn together to make a single machine capable of flight. In fact, it is capable of flight in any direction – backwards, forwards, sideways, up, down, and even standing still! Standing still is known as “hoveringâ€; or, as a Dutch friend of mine was wont to say, “hooveringâ€. This comes in handy for those who like flying but have no place to go. Helicopters are normally flown by individuals who don’t like to stray far from the airport or who are known have narcissistic tendencies. In fact, as a group, helicopter pilots have long been suspected of self-abuse.
One of the more necessary components is the engine. This unit is expected to start with ordinary fuel; change the fuel to BTU, the BTU to BMEP, and the BMEP to RPM. The RPM is then transmitted through a series of shafts and gears to the main rotor blades that are responsible for the frantic eggbeater motion characteristic of the beast.
The engine has several important parts. Among those are cylinders. A cylinder is a long hole covered on one end with a plate full of smaller holes containing valves. The holes admit air and fuel…and sometimes water and carelessly misplaced tools. The other end is closed with a plug called a piston. This is free to move up and down and would come out altogether if it were not fastened to a connecting rod. The other end of the connecting rod is affixed to a crank shaft. By themselves, the piston and the connecting rod are well nigh useless for all they do is produce BMEP. However, the crank shaft is extremely important: it is responsible for converting your BMEP to RPM. Without RPM, you would be left with BMEP and some leftover BTU, which, by themselves, are not worth a pitcher of warm spit.
The output of the engine is measured in horsepower. No one knows why… It is often difficult to get a self-respecting horse within seventy yards of one of these machines. There was talk that a fellah named Jimmy Watt found that a mine pony could lift 22000 pounds one foot in one minute, added fifty percent and called the resulting figure “one horsepowerâ€. However, as no one uses horses in coal mining anymore, it’s anyone’s guess as to its real meaning today. For that reason, it’s better to rely on instruments the electrical men have invented to measure power. They indicate power in amps, volts, or kilowatts, depending on the individual whims of the designer. With a little imagination and an E6B, these values can be converted into horsepower.
Starting the “thing†requires some knowledge of quantum mechanics, steady nerves, and a certain amount of ‘je ne sais quoi’, which is French for “two over easy, toast on the sideâ€. First, make a careful check of all your instruments. When converting to a new machine, many helicopter pilots make an accurate count of the cockpit instruments on their first trip. Subsequent instrument checks can then be reduced to counting; if there are supposed to be ten gauges in the cockpit and ten gauges are found, the machine is serviceable. This procedure not only gives you a little self-confidence, but also adds prestige in the eyes of the onlookers. After everything has been checked, then – and only then – is it safe to start the engine. If everything is as it should be – air, fuel, spark, Marvel Mystery oil - there will be considerable noise and the machine will commence to shake, tremble, and rock from side to side. This is a good sign that the engine has started. If the rotor has commenced to turn any time during this procedure, it is visual proof that the mast has not broken during the procedure.
When your audience has returned, synchronize your eyeballs and look wisely at the instrument panel, noting pressure and RPM. Before you forget, check the flight controls. This is important even though the controls quite often do not perform the function for which they were designed. It is embarrassing to get into the air and find these items not working properly…or, worse, not working at all! Once airborne, you are on your own: astride a brute that, like a bumblebee, looks as though it won’t fly, knows that it can’t fly, but does so anyway and to Hell with it!
The controls of a helicopter do not work like the controls in a fixed wing aircraft: for instance, the stick (cyclic) has no feel nor rigidity and if not held securely at all times, will fall to the floor or bounce off the instrument panel resulting in expressions of concern from the passengers. The anti-torque pedals are somewhat akin to the rudder pedals in that they both provide a resting spot for your feet. However, unlike the rudder pedals, the sole job of the anti-torque pedals is to keep the blunt end forward - except in the “hoover†when their job is to make the passengers dizzy.
The collective is the stick thingy to the left of the pilot’s seat: its job is to convert the RPM and BMEP into lift. The means by which it does so is known only to some senior helicopter pilots who are extremely secretive about the whole operation, but I have included a lay-person’s explanation further down. For practical purposes, suffice it to say that pulling on the lever causes things to get smaller while pushing on the lever will cause the reverse effect. Through some interconnect between the controls; the collective can also make the machine accelerate. Again, the process is rather ambiguous and not normally discussed in polite circles. However, the collective has an active part to play in a quick descent procedure called “autorotationâ€; more about which later.
When all the tickets have been collected, it is wise to go flying before anyone can change their minds. To get airborne is a rather technical affair and involves momentarily nullifying the Attraction Law; the principle which keeps all things on the ground. The principle states that two objects have an attraction to one another and the larger the mass, the larger the attraction. Momentarily null the Law of Attraction by pulling up on the collective and the Law of Rejection becomes prime and the helicopter leaves the ground. As long as the collective lever is off the stop and the engine is running, the helicopter will fly. However, if the engine fails, one of the two main requirements of flight - motive power – has been removed and immediate action it required.
To get the helicopter going down, the Law of Attraction must be reintroduced by lowering the collective. This will produce a descent around 1500-2000 feet per minute and can cause unsecured items in the cockpit to float up around eye level. Dependant on the time since ingestion, these items may be intermingled with various passenger lunch bits.
Once the helicopter has reached an altitude between 75-100 feet above ground and near terminal velocity, its descent and forward speed must both be slowed to near zero before contact with any surface: this is achieved by the judicious use of the collective to maintain a fine balance between the Laws of Attraction and Rejection. Too much one way or the other can lead to disastrous results. This level of expertise comes with time and damage to at least three helicopters. However, most of the machines are repairable.
It should be noted that in the helicopter world, most students are sent solo at this stage.
In the second part, we will explore lead, lag, and flap back and discuss why helicopter time in the logbook is viewed in the same light as VD in a medical record.
LOVE THAT EGGBEATER
(Many of us belong to an exclusive club – those who understand the terms lead, lag, and flapback. For those who are convinced that helicopters are just collections of stuff going the same way the same day, I submit the following which was based on a Bell 47…)
PART 1
The helicopter is an amazing assortment of nuts, bolts, rotors, push-pull rods, irreversibles, longitudinal collective differential quadrants, swash plates, wobble plates, gimble rings, cuff links, trunion assemblies and other gadgets too humorous to mention. All of these are welded, riveted, bolted or sewn together to make a single machine capable of flight. In fact, it is capable of flight in any direction – backwards, forwards, sideways, up, down, and even standing still! Standing still is known as “hoveringâ€; or, as a Dutch friend of mine was wont to say, “hooveringâ€. This comes in handy for those who like flying but have no place to go. Helicopters are normally flown by individuals who don’t like to stray far from the airport or who are known have narcissistic tendencies. In fact, as a group, helicopter pilots have long been suspected of self-abuse.
One of the more necessary components is the engine. This unit is expected to start with ordinary fuel; change the fuel to BTU, the BTU to BMEP, and the BMEP to RPM. The RPM is then transmitted through a series of shafts and gears to the main rotor blades that are responsible for the frantic eggbeater motion characteristic of the beast.
The engine has several important parts. Among those are cylinders. A cylinder is a long hole covered on one end with a plate full of smaller holes containing valves. The holes admit air and fuel…and sometimes water and carelessly misplaced tools. The other end is closed with a plug called a piston. This is free to move up and down and would come out altogether if it were not fastened to a connecting rod. The other end of the connecting rod is affixed to a crank shaft. By themselves, the piston and the connecting rod are well nigh useless for all they do is produce BMEP. However, the crank shaft is extremely important: it is responsible for converting your BMEP to RPM. Without RPM, you would be left with BMEP and some leftover BTU, which, by themselves, are not worth a pitcher of warm spit.
The output of the engine is measured in horsepower. No one knows why… It is often difficult to get a self-respecting horse within seventy yards of one of these machines. There was talk that a fellah named Jimmy Watt found that a mine pony could lift 22000 pounds one foot in one minute, added fifty percent and called the resulting figure “one horsepowerâ€. However, as no one uses horses in coal mining anymore, it’s anyone’s guess as to its real meaning today. For that reason, it’s better to rely on instruments the electrical men have invented to measure power. They indicate power in amps, volts, or kilowatts, depending on the individual whims of the designer. With a little imagination and an E6B, these values can be converted into horsepower.
Starting the “thing†requires some knowledge of quantum mechanics, steady nerves, and a certain amount of ‘je ne sais quoi’, which is French for “two over easy, toast on the sideâ€. First, make a careful check of all your instruments. When converting to a new machine, many helicopter pilots make an accurate count of the cockpit instruments on their first trip. Subsequent instrument checks can then be reduced to counting; if there are supposed to be ten gauges in the cockpit and ten gauges are found, the machine is serviceable. This procedure not only gives you a little self-confidence, but also adds prestige in the eyes of the onlookers. After everything has been checked, then – and only then – is it safe to start the engine. If everything is as it should be – air, fuel, spark, Marvel Mystery oil - there will be considerable noise and the machine will commence to shake, tremble, and rock from side to side. This is a good sign that the engine has started. If the rotor has commenced to turn any time during this procedure, it is visual proof that the mast has not broken during the procedure.
When your audience has returned, synchronize your eyeballs and look wisely at the instrument panel, noting pressure and RPM. Before you forget, check the flight controls. This is important even though the controls quite often do not perform the function for which they were designed. It is embarrassing to get into the air and find these items not working properly…or, worse, not working at all! Once airborne, you are on your own: astride a brute that, like a bumblebee, looks as though it won’t fly, knows that it can’t fly, but does so anyway and to Hell with it!
The controls of a helicopter do not work like the controls in a fixed wing aircraft: for instance, the stick (cyclic) has no feel nor rigidity and if not held securely at all times, will fall to the floor or bounce off the instrument panel resulting in expressions of concern from the passengers. The anti-torque pedals are somewhat akin to the rudder pedals in that they both provide a resting spot for your feet. However, unlike the rudder pedals, the sole job of the anti-torque pedals is to keep the blunt end forward - except in the “hoover†when their job is to make the passengers dizzy.
The collective is the stick thingy to the left of the pilot’s seat: its job is to convert the RPM and BMEP into lift. The means by which it does so is known only to some senior helicopter pilots who are extremely secretive about the whole operation, but I have included a lay-person’s explanation further down. For practical purposes, suffice it to say that pulling on the lever causes things to get smaller while pushing on the lever will cause the reverse effect. Through some interconnect between the controls; the collective can also make the machine accelerate. Again, the process is rather ambiguous and not normally discussed in polite circles. However, the collective has an active part to play in a quick descent procedure called “autorotationâ€; more about which later.
When all the tickets have been collected, it is wise to go flying before anyone can change their minds. To get airborne is a rather technical affair and involves momentarily nullifying the Attraction Law; the principle which keeps all things on the ground. The principle states that two objects have an attraction to one another and the larger the mass, the larger the attraction. Momentarily null the Law of Attraction by pulling up on the collective and the Law of Rejection becomes prime and the helicopter leaves the ground. As long as the collective lever is off the stop and the engine is running, the helicopter will fly. However, if the engine fails, one of the two main requirements of flight - motive power – has been removed and immediate action it required.
To get the helicopter going down, the Law of Attraction must be reintroduced by lowering the collective. This will produce a descent around 1500-2000 feet per minute and can cause unsecured items in the cockpit to float up around eye level. Dependant on the time since ingestion, these items may be intermingled with various passenger lunch bits.
Once the helicopter has reached an altitude between 75-100 feet above ground and near terminal velocity, its descent and forward speed must both be slowed to near zero before contact with any surface: this is achieved by the judicious use of the collective to maintain a fine balance between the Laws of Attraction and Rejection. Too much one way or the other can lead to disastrous results. This level of expertise comes with time and damage to at least three helicopters. However, most of the machines are repairable.
It should be noted that in the helicopter world, most students are sent solo at this stage.
In the second part, we will explore lead, lag, and flap back and discuss why helicopter time in the logbook is viewed in the same light as VD in a medical record.