Thermal Interface Material Tester (TIM-Tester)


On point

Waste heat management, thermal runaway protection in batteries and electronic packaging is becoming more and more important as power densities of these devices increase. Thermal management of these complex systems is not trivial and requires a fundamental understanding of how components and interface materials work together to shed heat.

Our LINSEIS Thermal Interface Material Tester (TIM-Tester) is the perfect solution for thermal management optimization of these complex systems.

The TIM Tester measures the thermal impedance of sample materials and identifies an apparent thermal conductivity for a wide range of materials from liquid compounds and pastes to hard solid materials. The approach is consistent with the ASTM D5470 – standard.

  • Automatic pressure adjustment using electric actor (up to 8 MPa)
  • Automatic thickness determination using high resolution LVDT
  • Instruments working according to ASTM D5470
  • Full integrated, software controlled device
L82 TIM Tester sample

Thermal interface materials such as thermal fluids, thermal pastes (greases), phase change materials (PCM), solders or resilient thermal conductors are tested automatically by applying a pressure of up to 8 mPa (for ø 20mm sample) and Temperature of up to 300°C at the hot side.

The software interface allows the instrument to be operated automatically over a wide temperature and pressure range, while all test parameters are recorded in real time. This allows the user the freedom to fully explore an experimental design space for materials optimization. The sample holder is designed with sample size and shape flexibility in mind to accommodate actual size parts.

Typical samples include solids, pastes, pads and more. Different meter bars for varying applications (depending on thermal impedance of the sample materials and temperature range).

exchangeable meter bars


A sample is positioned between a hot and a cold meter bar, where the hot meter bar is connected to a regulated heating stage and the cold meter bar is connected to a thermostatically control¬led, liquid cooled heat sink. The contact pressure on the sample can be automatically adjusted with an integrated electric actor (in terms of pressure stability over temperature). The sample dimension (thickness) can either be entered manually or can be measured (and controlled) using an integrated sensor.

The heat flux through the sample is measured using several temperature sensors which are located in a known distance inside of each of the meter bars. The thermal impedance can be obtained from the temperature drop caused by the sample material using its geometry for the calculation. For obtaining the apparent thermal conductivity, the thermal impedance for a single and a multiple layered specimen can be plotted against the thickness of the respective specimen.

Sectional view of the L82-Setup 


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Black and white

Detailed view of the Meter Bar


Model TIM-Tester
Sample size: from ø 20 mm to ø 40 mm
from 20 x 20 mm to 40 x 40 mm
Thickness: 0.01 mm up to 15 mm
Other sizes on request
Sample types: solids, powders, pastes, foils, liquids, adhesives
Thickness measurement accuracy: +/- 0.10 % at 50% stroke
+/- 0.25 % at 100% stroke
Resistance range: 0.01 K/W – 8 K/W
Temperature range: RT up to 150°C
RT up to 300°C (on request)
Temperature accuracy: 0.1°C
Thermal conductivity range: 0.1 up to 50 W/m∙K (extended range on request)
Contact pressure range: 0 up to 8 MPa (depending on sample size)
Contact pressure accuracy: +/- 1%
Dimensions: 675 mm H x 550mm W x 680 mm D
Cooling system: external chiller (in combination with a additional heater)
Heating system: Resistance heater


The all new Rhodium Software greatly enhances your workflow as the intuitive data handling only requires minimum parameter input. AutoEval offers a valuable guidance for the user when evaluating standard processes such as thermal impedance or thermal conductivity determination.

Linseis LFA 500 Software

    • Software packages are compatible with latest Windows operating system
    • Set up menu entries
    • Software packages are compatible with latest Windows operating system
    • Software controlled heating, cooling or dwell time segments
    • Software controlled thickness determination, force/pressure adjustment
    • Easy data export (measurement report)
    • All specific measuring parameters (User, Lab, Sample, Company, etc.)
    • Optional password and user levels
    • Multiple language versions such as English, German, French, Spanish, Chinese, Japanese, Russian, etc. (user selectable)


Application: Measurement of Vespel™ (at 50°C, 1MPa)

Measurement of Vespel™ (at 50°C, 1MPa)

Measurement of the thermal impedance (thermal conductivity) of a 25mm x 25mm Vespel™ sample at 50°C (TH=70°C, TC=30°C) and a contact pressure of 1 MPa. Three different samples with a thickness between 1,1 mm and 3,08 mm have been measured in order to determine the apparent thermal conductivity and thermal contact resistance (using linear regression).

Application: Temperature dependent measurement of Vespel™

Temperature dependent measurement of Vespel™

Plot of the temperature dependent apparent thermal conductivity of a 25mm x 25mm Vespel™ sample between 40°C and 150°C and a constant contact pressure of 1 MPa.

Application: Temperature dependent measurement of Vespel™

TIM Tester: Measurement of type 2 thermal pad (at 50°C)

Measurement of the thermal impedance (thermal conductivity) of a 25mm x 25mm thermal conductive pad (sample type 2) at 50°C (TH=70°C, TC=30°C). Three different samples with a thickness between 2.01 mm and 3.02 mm have been measured in order to determine the thermal contact resistance (using linear regression).

Application: Possible sample types

Type I
Viscous liquids that exhibit unlimited deformation when a stress is applied. These include liquid compounds such as greases, pastes, and phase change materials. These materials exhibit no evidence of elastic behavior or the tendency to return to initial shape after deflection stresses are removed.

Type II
Viscoelastic solids where stresses of deformation are ultimately balanced by internal material stresses thus limiting further deformation. Examples include gels, soft, and hard rubbers. These materials exhibit linear elastic properties with significant deflection relative to material thickness.

Type III
Elastic solids which exhibit negligible deflection. Examples include ceramics, metals, and some types of plastics.



TIM Tester Broschüre Download

TIM Tester brochure (PDF)