Insulation resistance, dielectric strength

ISO 16750-2

These tests provide information about the adequacy of galvanic isolation between specific points of the samples.

Measurement and monitoring of electrical characteristics

N/A

Measurement of voltage, current, resistance, capacitance, inductance, and time dependent characteristics, including long term data logging combined with ambient temperature measurement and operating mode simulations.

Automotive communication protocol signal monitoring

N/A

Monitoring of analog, PWM, PSI5, SENT, CAN, and LIN signals under environmental stress conditions combined with operating mode simulation.

Vibration, resonance

IEC 60068-2-6 (Sine)

IEC 60068-2-64 (Random)

ISO 16750-3

These tests provide information about the mechanical and functional resistance of the samples against various vibration loads.

Mechanical shock resistance

IEC 60068-2-27

ISO 16750-3

These tests provide information about the mechanical and functional resistance of the samples against mechanical shocks.

Free fall

IEC 60068-2-31

ISO 16750-3

These tests provide information about the mechanical and functional failures that may occur as a result of dropping the samples.

Stone impact

ISO 20567-1

ISO 16750-3

These tests provide information about the mechanical and functional resistance of the samples against stone impact loads.

Tensile and compressive force tests (static and dynamic)

N/A

These tests provide information about the mechanical resistance of the samples.

Constant low temperature exposure

Constant high temperature exposure

IEC 60068‑2‑1:2007 – Test A: Cold

ISO 16750-4

IEC 60068‑2‑2:2007 – Test B: Dry heat

ISO 16750-4

These types of climatic tests simulate the effects of prolonged exposure to extreme temperatures on the sample. According to procedure, the samples are placed in a climate chamber set to a stable temperature for a specified duration. The results allow us to verify whether the samples have adequate resistance for long term storage, transportation, or operation.

Constant high temperature and high humidity exposure

IEC 60068-2-78:2012

Test Cab: Damp heat, steady state

IEC 60068-2-67ISO 16750-4

During the test, the primary objective is to evaluate whether electronic products are capable of maintaining fault free operation when consistently exposed to high humidity conditions.

Thermal shock in air

IEC 60068-2-14:2023

Test Na: Rapid change of temperature

ISO 16750-4

Thermal shock testing is an effective method for evaluating the durability and reliability of materials or products exposed to extreme temperature changes. The purpose of the test is to identify potential weaknesses and material failures caused by thermal expansion and contraction.

During the test, the samples are rapidly transferred between a low temperature and a high temperature chamber, reproducing the environmental stress known as ‘thermal shock’, that occurs during real world use.

Temperature change with specified rate

IEC 60068-2-14:2023

Test Nb: Change of temperature with specified rate of change

ISO 16750-4

Similar to air based thermal shock testing, the goal is to identify potential weaknesses and material defects caused by thermal expansion and contraction. However, unlike classic thermal shock testing, this method is performed within a single chamber, where the temperature changes at a specified °C/min rate. As a result, the nature of the thermal load applied to the samples is fundamentally different.

Thermal shock in iced water

ISO 16750‑4:2023

This test simulates the thermal shock effect caused by water splashing onto vehicle components. A real life example of this phenomenon occurs when a vehicle operating at normal temperature drives on wet surfaces during colder seasons. The test helps identify failures resulting from differing thermal expansion coefficients of the product’s materials, which may lead to mechanical cracks or sealing issues.

Thermal shock in liquid

IEC 60068-2-14 Test Nc

These tests provide information about the mechanical and functional resistance of the samples against rapid temperature changes. The samples are alternately immersed in two baths—one filled with a low temperature liquid and the other with a high temperature liquid. This method subjects the samples to a significantly stronger thermal shock load than air based thermal shock testing.

Splash water

ISO 16750-4

These tests provide information about the mechanical and functional resistance of the samples against rapid temperature changes. The samples are alternately immersed in two baths, one filled with a low temperature liquid and the other with a high temperature liquid. This method subjects the samples to a significantly stronger thermal shock load compared to air based thermal shock testing.

Salt mist / corrosion test

IEC 60068-2-11:2021

Test Ka: Salt mist

IEC 60068-2-52

ISO 16750-4

ISO 9227

During this test, we artificially, and in a controlled manner reproduce the corrosion effects that products may experience throughout their lifecycle by generating a corrosive atmosphere—typically salt mist—inside a sealed chamber. The outcome of the test is the determination of the samples’ resistance to corrosion.

Dust ingress protection (IP6KX)

ISO 20653

These tests provide information about the samples’ protection against dust ingress.

Water ingress protection (IPX4/4K/7/9K)

ISO 20653

These tests provide information about the samples’ resistance to water ingress, including protection against splashing water, immersion, and high pressure washing.

Sectioning / sample preparation

N/A

A destructive process used to prepare the samples for subsequent visual inspection.

Crack detection

N/A

Crack inspections performed using cesium chloride or Magnaflux reagent materials, which provide information about mechanical damage originating from the surface of the samples and affecting their tightness.

Optical microscopy

N/A

These tests are used for the visual inspection of the samples through high resolution images.

Scanning Electron Microscopy (SEM)

N/A

These examinations serve for the visual inspection of the samples using ultra high resolution images. They can also provide information about the material composition and material density of the samples.

X‑ray and CT inspection

N/A

Non‑destructive internal inspection of samples.