Order Analysis
Order analysis relates measurements to revolutions of a rotating part, improving knowledge about machinery such as aircraft and automotive engines, powertrains, pumps, compressors and electric motors.
Order analysis relates measurements to revolutions of a rotating part, improving knowledge about machinery such as aircraft and automotive engines, powertrains, pumps, compressors and electric motors.
Machine diagnostic techniques are extremely effective because they directly use the information contained in the machine vibration signature.
Often used to monitor critical helicopter gearboxes, HUMS is also increasingly used to monitor gas turbines – both in helicopters and in certain fixed-wing aircraft. HBK supplies a range of extremely robust and reliable HUMS sensor solutions.
Airframers face stringent requirements to reduce fuel burn, environmental emissions and engine noise, drawing engine performance into central focus. HBK’s gas turbine test systems provide comprehensive testing, data recording, and real-time analysis to ensure data validity.
A good condition of the bearings is one of the decisive factors for a pleasant riding experience. Acquiring and analysing train pass-by noise with HBK devices helps operators to monitor the bearing condition and optimise their maintenance schedule.
Monitoring the condition of electrical machines is a challenge. Electrical interferences and high voltages affect signal quality and safety. Our optical measurement solutions are ideal for monitoring strain, vibration, and temperature on these assets.
Machine analysis and diagnostics help you identify energy emissions caused by noise and vibration, which could explain inefficiency in machinery.
Noise and vibration aren’t just annoying; they represent energy emissions that indicate inefficiency in machinery. Noise and vibration indicate issues that can affect a machine's reliability, such as imbalanced parts, and can even cause machines to fail through their own damaging effects.
Rotating or reciprocating equipment such as compressors, power trains, engines, pumps and turbines, are constructed of many parts that each contribute to the sound and vibration pattern of the whole assembly. In these types of machinery, varying load conditions and imbalances caused by imperfections or uneven mass can result in vibration and associated noise. Achieving efficiency and minimizing vibration requires the detection of these faults and imbalances; however, they can never be entirely eliminated. Thus, when incorporating a machine into another structure – like an aircraft engine – it’s important to understand the machine’s vibration output to avoid consequences such as exciting structural resonances.
Understanding the vibration output of a machine requires analyses that can correlate vibration measurements with the machine’s processes. Order analysis relates vibration measurements to the revolutions of a rotating part, improving knowledge about machinery such as powertrains, pumps, compressors and electric motors. It’s important to be able to incorporate the machine’s own parameters, such as oil pressure and RPM, into the analysis via CAN Bus or auxiliary inputs.
Changes in a machine’s vibration patterns can be indicative of machinery health. By diagnosing and addressing vibration problems in rotating and reciprocating machinery, performance can be optimized.
Monitoring machine health ensures deterioration and fatigue failures can be prevented, maximizing productive uptime and allowing better scheduling of maintenance, repair, and overhaul (MRO) procedures, with more confidence between scheduled stops.