Current research projects

Image Influenced melting point of water by magnetic field
Image Helium extraction from natural gas
Image In-situ investigation concerning the swelling behaviour of polymer materials under elevated pressures and temperatures
Image Development of test methods and test rigs for stationary integrated refrigeration units
Image Certification of efficient air conditioning and ventilation systems through the new "indoor air quality seal" for non-residential buildings
Image Corrosion inhibitor for ammonia absorption systems
Image Intelligent innovative power supply for superconducting coils
Image Low noise and non metallic liquid-helium cryostat
Image Service offer for Leak Detection and Tightness Test
Image Tensile and compression testing
Image Performance tests of refrigerant compressors
Image Tribological investigations of oil-refrigerant-material-systems
Image Filter Tests
Image Test procedures for electrical components
Image Modular storage system for solar cooling
Image IO-Scan - Integral measuring optical scanning method

You are here:   /  Home


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


Your Request

Further Projects