Current research projects

Image 3D - Air flow sensor
Image Tribological investigations of oil-refrigerant-material-systems
Image Cryogenic liquid piston pumps for cold liquefied gases like LIN, LOX, LHe, LH2, LNG, LAr
Image Verification of storage suitability of cryo tubes
Image Service offer for Leak Detection and Tightness Test
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 Performance tests of condensing units
Image Range of services laboratory analyses
Image Low Temperature Measuring Service
Image Micro heat exchangers in refrigeration
Image Micro fluidic expansion valve
Image Air-water heat pumps
Image Test rigs for refrigeration and heat pump technology
Image Combined building and system simulation
Image Influenced melting point of water by magnetic field

You are here:  Home /  Consulting, Expert Opinions


Lifetime prediction of hermetic compressor systems

Wolfgang Hernschier

+49-351-4081-5417

Partial discharges in motor windings

In the field of refrigeration and air conditioning technology, speed-controlled compressors are increasingly being used. In addition to stationary refrigeration, this also applies in particular to the automotive sector, where frequency converter-fed electric motors are being used for compressors in the course of the spread of e-mobility. The use of frequency converters is associated with a pulse-shaped voltage stress on the motor windings in the compressors. This results in an overshoot of the voltage (especially with longer motor cables), which leads to higher stress on the insulation compared to operation with sinusoidal voltage.

 

These pulses can lead to partial discharges (PD) on and in the insulation and represent a high stress for the insulation systems of the motor windings.

In addition to this electrical stress on the insulating materials, there are other influencing factors, particularly in refrigerant compressors, which cause the insulating system to age, especially thermal and chemical effects. For investigations on the winding insulations of refrigerant compressors, the chemical factors influencing aging should therefore be taken into account. These interactions significantly complicate the service life prediction for the winding insulation of refrigerant compressor motors.

The aim of the project is to develop test setups and procedures that will enable the evaluation and optimization of insulation systems for motor windings of refrigerant compressors with regard to service life during frequency converter operation.

The following problems are addressed in the project:

  • How does the insulation system behave under pulse voltage in refrigerant-oil atmosphere (gas, pressure, temperature, water content, oil wetting, voltage parameters)?
  • When do partial discharges occur in the stator under operating conditions (dependence on winding structure)?
  • Can the service life of the winding insulation be predicted based on time-lapse tests of wire windings, and if so, how?
  • By what test method can the PD strength of flat wire insulation be assessed?

New test setups to be developed, a pulse generator and PD measurement technology are to be used to investigate the influence of the refrigerant and oil, the voltage parameters (voltage level, pulse length, frequency, edge steepness, polarity) on the partial discharge behavior and the service life of enameled wires and stators under refrigerant-oil atmosphere. Based on these investigations, a method for predicting the service life of motor insulation systems in terms of partial discharge resistance will be developed.


Your Request

Further Projects - Consulting, Expert Opinions

Image

Measurement of insulated packaging

How efficient is my cool box?

Image

Energy efficiency consulting - cogeneration systems

How efficient is my refrigeration system?

Image

Preformance measurements of heat exchangers

Is the heat exchanger properly sized?

Image

Investigation of coolants

Secondary loop refrigerants

Image

Refrigerants, lubricants and mixtures

Determination of working fluid properties