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Image Software for test rigs
Image Multifunctional electronic modules for cryogenic applications
Image Swirl-free on the move...
Image In-Situ-Swelling Behaviour of Polymer Materials in Flammable Fluids
Image In-situ investigation concerning the swelling behaviour of polymer materials under elevated pressures and temperatures
Image Investigation of coolants
Image Tribological investigations of oil-refrigerant-material-systems
Image Development of a Cryogenic Magnetic Air Separation Unit
Image Helium extraction from natural gas
Image Micro fluidic expansion valve
Image Reducing the filling quantity

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Investigation according to DIN EN ISO 14903

Dipl.-Ing. (FH) René Seidel

+49-351-4081-5428

These tests according to DIN EN ISO 14903 are possible at ILK Dresden

§7.4 Tightness Test

§7.6 Pressure- Temperature- Vibration Test

§7.7 Simulation Operating

§7.8 Freezing Test

§7.9 Pressure Test

§7.10 Vacuum Test

§7.11 Compatibility Test

§7.12 Fatigue Test

 

§7.4 Tightness Test

  • Tightness control according to classification in DIN EN ISO 14903 at room temperature
  • In each case per connection or component (test sample) before and after the respective modules
  • Permissible leakage rate (helium) depending on the selected tightness control level E.g. A1 with Q ≤ 7,5E-7 Pa m³/s = 7,5E-6 mbar l/s @ 10 bar rel., 20 °C

  • Testing with helium gas detector in vacuum method or substitute method

  • Procedure section 10 according to DIN EN 13185, Detection limit 5,0E-13 Pa m³/s helium

  • Test gas helium

§7.6 PTV Test and if necessary §7.7 Simulation Operating

  • Tmin: -40 °C (specified by the customer)
  • Tmax: +140 °C (specified by the customer)
  • Test pressure PSmax: 100 bar rel. (specified by the customer)
  • 50 Temperature changes
  • 200 Pressure pulses
  • Subsequent vibration test < 200 Hz, 1 Axis, 2 Mio vibrations, const. amplitude
  • Simulation Operating, E.g. 25x open and close the connection

§7.8 Freezing Test

  • Freezing test in a vacuum test chamber. The test specimen is exposed in a vacuum chamber filled with water at 500 mbar abs (+ 0, -100 mbar) for at least 10 min. The pressure is then increased to atmospheric pressure.

  • Afterward, the test specimens are stored at -15 °C (or below) for at least 30 min in a temperature-controlled cabinet and then exposed to water at ambient temperature for at least 5 min., these steps are repeated a total of 30 times

§7.9 Pressure Test

  • The pressure test is performed at 5xPS for 1 minute
  • Medium oil

§7.10 Vacuum Test

  • The test samples are subjected to the test to confirm that they are able to withstand a vacuum with an absolute pressure of 6.5 kPa for 1 h without leakage.
  • For this purpose, the pressure is monitored and it is checked whether the pressure increase Δp after 1 h is less than 0.2 kPa. The effect of the temperature change on the pressure is taken into account.

§7.11 Compatibility Test

  • Investigation into the chemical compatibility of the materials

  • Aging for 336 h at 50 °C in refrigerant-oil atmosphere (for elastomer materials)

  • Aging for 1000 h at 50 °C in refrigerant-oil atmosphere (for thermoplastic materials)

  • Determination of mass, volume and hardness before and after aging

§7.12 Fatigue Test

  • Fatigue test, 250.000 Pressure cycles at max. 50 changes per minute

  • Test range between test pressure PS and atmospheric pressure, test medium: water


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