LSAs: Who?s guarding the henhouse?
March 3, 2016 Mike Busch
Illustration by Daniel Hertzberg
Editor's Note: An earlier version of this story incorrectly identified a Normal category airplane that uses the Rotax 912S. AOPA regrets the error.
Opinion |
This year for the first time I attended the U.S. Sport Aviation Expo in Sebring, Florida, the foremost aviation event devoted to Light Sport and ultralight aircraft. I accepted an invitation to speak not because I had any expertise in this lightweight corner of the general aviation envelope, but because I sensed this would be a great opportunity to learn about an exciting and rapidly growing segment of GA.
In 2004, the FAA approved new regulations that created sport pilots and Light Sport aircraft. I recall wondering whether this would amount to much. I needn?t have worried. There are now more than 6,000 sport pilots and nearly 4,000 registered LSAs, making this the fastest-growing segment of GA.
Ten years ago, the term ?LSA? conjured up images of small, tube-and-fabric designs that always struck me as a lot more ?sport? than ?airplane.? But progress over the past decade has been astonishing?especially compared to the glacial pace we?re used to in the certified world. Today?s top-selling factory-built LSAs, called Special Light Sport aircraft (SLSAs), are sleek, sexy, high-tech designs with sophisticated powerplants and glass cockpits.
A lot of this progress in the LSA world has been spurred by two component suppliers: Dynon Avionics and Rotax Aircraft Engines. The Dynon Skyview seems to be the de facto standard avionics suite for the current crop of SLSAs, and it has capabilities that put to shame most of the TSOed glass cockpit suites I?ve seen.
The 100-horsepower Rotax 912ULS powers about 80 percent of new SLSAs. Rotax started out building two-stroke engines used in snowmobiles, personal watercraft, ATVs, and outboard motors, as well as in go-karts and ultralights. Those engines were famous for being cheap and light, but in aviation applications a bit cantankerous and dismally short-lived (three-digit TBOs). Rotax created its four-stroke 900 series as a clean-sheet design specifically for the aviation market, employing Nikasil nickel-carbide cylinder barrels, liquid-cooled heads, and electronic ignition. The original 500-hour TBO has been increased to 2,000 hours, accompanied by a record of impressive durability and reliability.
Who?s guarding the henhouse?
The FARs treats LSAs very differently from either certificated or amateur-built aircraft in ways that are sometimes good, sometimes bad, and sometimes bizarre. LSAs are not certified by the FAA in the traditional sense: They don?t have a type certificate and don?t need to meet FAA certification standards the way Normal-category airplanes do. Instead, LSAs are required to conform to something called ?FAA-accepted ASTM Consensus Standards.?
Members of nonprofit ASTM International, a voluntary standards development organization, create and maintain 12,000 consensus industry standards in such diverse areas as metals, textiles, petroleum, construction, energy, consumer products, medical services, and electronic devices. ASTM Committee F37 on Light Sport aircraft develops standards for LSAs. About 200 members represent manufacturers, suppliers, distributors, and industry alphabet groups. Seven technical subcommittees have jurisdiction over 24 consensus standards, ranging from minimum safety and performance requirements to quality assurance, flight testing, and maintenance.
In essence, the FAA has stepped back from its traditional regulatory role and allowed LSA manufacturers and ASTM F37 to run the show. This strikes me as a mixed blessing. It has clearly been a boon to the LSA industry, facilitating technical progress that I doubt would have been possible in a conventional, FAA-regulated certification environment. It also has put LSA owners in a situation in which everything the manufacturers do or say has the force of law, and that seems a bit like having the fox guard the henhouse.
FAR 91.327 imposes a laundry list of operating limitations on SLSAs, many of which sound reasonable. For example, it prohibits the use of SLSAs for compensation or hire except to conduct flight training or tow gliders. It requires condition inspections every 12 calendar months (every 100 hours if the SLSA is used for hire). It requires owners to comply with applicable airworthiness directives?all commonsense stuff.
But 91.327 also requires SLSA owners to comply with ?each safety directive applicable to the aircraft that corrects an existing unsafe condition.? These safety directives are issued by the manufacturer, so in effect they?re mandatory service bulletins?owners of certificated aircraft operating under Part 91 must comply with service bulletins only if the FAA issues an AD compelling compliance. In essence, LSA manufacturers can issue their own ?ADs? without having to jump through the statutory hoops that protect owners from unreasonable action by the FAA.
It gets worse. FAR 91.327(d) requires that SLSA pilots ?must operate the aircraft in accordance with the aircraft?s operating instructions.? If this rule applied to Normal category aircraft, it would be an FAR violation for me to operate my engines lean of peak, because that?s not what the pilot?s operating handbook says to do. Nor could I purchase GAMIjectors to make lean-of-peak operation practical, because FAR 91.327 says that any major alteration to an SLSA must be approved by the manufacturer.
The absurdity of this situation really hit home when I learned that SLSAs are prohibited from flying in IMC. I?m instrument-rated and current. My new quarter-million-dollar SLSA is equipped with wall-to-wall glass, synthetic vision, highway-in-the-sky graphics, and a fancy autopilot?and you?re telling me I can?t fly through clouds?
I looked for the regulation that prohibits SLSAs from operating in IMC, and discovered something interesting: There is no such regulation. It?s actually the LSA manufacturers that have decided not to allow their airplanes to be used this way.
Originally, it was perfectly legal for an appropriately rated pilot to fly an appropriately equipped SLSA in IMC. The original ASTM consensus standards were silent on the subject of IFR. Then, in 2010, the ASTM F37 Committee voted to amend the consensus standards to prohibit flight in IMC. Every SLSA manufactured since then has had operating limitations prohibiting IFR operations. At the time, the committee said this was intended to remain in effect only until it could develop an appropriate set of safety, performance, and equipment standards for IFR operation. That was six years ago, and according to folks who serve on the committee, the prohibition is unlikely to be lifted anytime soon.
...cont'd....
March 3, 2016 Mike Busch
Illustration by Daniel Hertzberg
Editor's Note: An earlier version of this story incorrectly identified a Normal category airplane that uses the Rotax 912S. AOPA regrets the error.
Opinion |
This year for the first time I attended the U.S. Sport Aviation Expo in Sebring, Florida, the foremost aviation event devoted to Light Sport and ultralight aircraft. I accepted an invitation to speak not because I had any expertise in this lightweight corner of the general aviation envelope, but because I sensed this would be a great opportunity to learn about an exciting and rapidly growing segment of GA.
In 2004, the FAA approved new regulations that created sport pilots and Light Sport aircraft. I recall wondering whether this would amount to much. I needn?t have worried. There are now more than 6,000 sport pilots and nearly 4,000 registered LSAs, making this the fastest-growing segment of GA.
Ten years ago, the term ?LSA? conjured up images of small, tube-and-fabric designs that always struck me as a lot more ?sport? than ?airplane.? But progress over the past decade has been astonishing?especially compared to the glacial pace we?re used to in the certified world. Today?s top-selling factory-built LSAs, called Special Light Sport aircraft (SLSAs), are sleek, sexy, high-tech designs with sophisticated powerplants and glass cockpits.
A lot of this progress in the LSA world has been spurred by two component suppliers: Dynon Avionics and Rotax Aircraft Engines. The Dynon Skyview seems to be the de facto standard avionics suite for the current crop of SLSAs, and it has capabilities that put to shame most of the TSOed glass cockpit suites I?ve seen.
The 100-horsepower Rotax 912ULS powers about 80 percent of new SLSAs. Rotax started out building two-stroke engines used in snowmobiles, personal watercraft, ATVs, and outboard motors, as well as in go-karts and ultralights. Those engines were famous for being cheap and light, but in aviation applications a bit cantankerous and dismally short-lived (three-digit TBOs). Rotax created its four-stroke 900 series as a clean-sheet design specifically for the aviation market, employing Nikasil nickel-carbide cylinder barrels, liquid-cooled heads, and electronic ignition. The original 500-hour TBO has been increased to 2,000 hours, accompanied by a record of impressive durability and reliability.
Who?s guarding the henhouse?
The FARs treats LSAs very differently from either certificated or amateur-built aircraft in ways that are sometimes good, sometimes bad, and sometimes bizarre. LSAs are not certified by the FAA in the traditional sense: They don?t have a type certificate and don?t need to meet FAA certification standards the way Normal-category airplanes do. Instead, LSAs are required to conform to something called ?FAA-accepted ASTM Consensus Standards.?
Members of nonprofit ASTM International, a voluntary standards development organization, create and maintain 12,000 consensus industry standards in such diverse areas as metals, textiles, petroleum, construction, energy, consumer products, medical services, and electronic devices. ASTM Committee F37 on Light Sport aircraft develops standards for LSAs. About 200 members represent manufacturers, suppliers, distributors, and industry alphabet groups. Seven technical subcommittees have jurisdiction over 24 consensus standards, ranging from minimum safety and performance requirements to quality assurance, flight testing, and maintenance.
In essence, the FAA has stepped back from its traditional regulatory role and allowed LSA manufacturers and ASTM F37 to run the show. This strikes me as a mixed blessing. It has clearly been a boon to the LSA industry, facilitating technical progress that I doubt would have been possible in a conventional, FAA-regulated certification environment. It also has put LSA owners in a situation in which everything the manufacturers do or say has the force of law, and that seems a bit like having the fox guard the henhouse.
FAR 91.327 imposes a laundry list of operating limitations on SLSAs, many of which sound reasonable. For example, it prohibits the use of SLSAs for compensation or hire except to conduct flight training or tow gliders. It requires condition inspections every 12 calendar months (every 100 hours if the SLSA is used for hire). It requires owners to comply with applicable airworthiness directives?all commonsense stuff.
But 91.327 also requires SLSA owners to comply with ?each safety directive applicable to the aircraft that corrects an existing unsafe condition.? These safety directives are issued by the manufacturer, so in effect they?re mandatory service bulletins?owners of certificated aircraft operating under Part 91 must comply with service bulletins only if the FAA issues an AD compelling compliance. In essence, LSA manufacturers can issue their own ?ADs? without having to jump through the statutory hoops that protect owners from unreasonable action by the FAA.
It gets worse. FAR 91.327(d) requires that SLSA pilots ?must operate the aircraft in accordance with the aircraft?s operating instructions.? If this rule applied to Normal category aircraft, it would be an FAR violation for me to operate my engines lean of peak, because that?s not what the pilot?s operating handbook says to do. Nor could I purchase GAMIjectors to make lean-of-peak operation practical, because FAR 91.327 says that any major alteration to an SLSA must be approved by the manufacturer.
The absurdity of this situation really hit home when I learned that SLSAs are prohibited from flying in IMC. I?m instrument-rated and current. My new quarter-million-dollar SLSA is equipped with wall-to-wall glass, synthetic vision, highway-in-the-sky graphics, and a fancy autopilot?and you?re telling me I can?t fly through clouds?
I looked for the regulation that prohibits SLSAs from operating in IMC, and discovered something interesting: There is no such regulation. It?s actually the LSA manufacturers that have decided not to allow their airplanes to be used this way.
Originally, it was perfectly legal for an appropriately rated pilot to fly an appropriately equipped SLSA in IMC. The original ASTM consensus standards were silent on the subject of IFR. Then, in 2010, the ASTM F37 Committee voted to amend the consensus standards to prohibit flight in IMC. Every SLSA manufactured since then has had operating limitations prohibiting IFR operations. At the time, the committee said this was intended to remain in effect only until it could develop an appropriate set of safety, performance, and equipment standards for IFR operation. That was six years ago, and according to folks who serve on the committee, the prohibition is unlikely to be lifted anytime soon.
...cont'd....