How to measure curing time and degree of cure - M100

Scope[edit | edit source]

This method uses resin hardness as a proxy to track the degree of cure (DOC) evolution for a curing thermoset resin. The method is based on the principle that increases in resin hardness correspond to increases in the resin degree of cure as chemical cross-links are formed, increasing the rigidity of the polymer.

While hardness can be measured by a variety of devices, the Barcol impressor (hardness tester) is recommended by ASTM (D2583) as appropriate for both reinforced and non-reinforced rigid plastics ^[4]. It is a relatively simple method to carry out, and requires minimal equipment.

The procedure description provided here is adopted from the Barcol Hardness test procedure in the Polynt Composites - Composites Applications Guide ^[1]. Fundamentally, this procedure is a derivation on ASTM D2583 – Standard Test Method for Indentation Hardness of Rigid Plastics by Means of a Barcol Impressor ^[4] – that is used to measure the hardness of cured polymers.

Setup[edit | edit source]

Equipment[edit | edit source]

Two separate Barcol hardness impressors are required to measure hardness for rigid plastics that are commonly used as polymer matrices. Switching between the Barcol impressors is dictated by the hardness of the material at the time it is being indented.

• Barcol 935 (softer materials)
• Barcol 934 (harder materials) - used when resin hardness is scale 75 and greater

Test Specimen[edit | edit source]

The hardness measurements can be made on production parts, as well as on purposely produced quality control laboratory samples. Barcol hardness measurements are not valid for gel coats as the specimen thickness is insufficient – inadvertently measuring the hardness of the material under the gel coat.

Minimum thickness: 0.8mm (1/32") - according to the Polynt ^[1] procedure, 1.5mm (1/16") - according to ASTM D2583 ^[4].

Measurement locations: Sample measurements should be made at positions at least 3mm away from the sample edges, and the test area should be smooth. If measuring a composite material containing fibre reinforcement, the measurement location ideally should be in an area of neat resin to avoid unwanted measurement of the fibre hardness.

Number of sample measurements: For a fully cured polymer, ASTM D2583 recommends at least 10 measurements ^[4] to be made to determine the resin hardness. However, taking hardness measurements while the resin is still curing (and hardening) to provide a 'snap-shot in time' requires that measurements be taken in quick succession, making this number of measurements difficult. The Polynt guide ^[1] specifies a minimum of 3 measurements. As a general rule of thumb, more variation is observed and therefore more measurements are required for softer material.

Procedure[edit | edit source]

The following procedure steps are a summary of those found in the Polynt Composites – Composites Applications Guide ^[1]:

1. Calibrate the Barcol impressor according to the manufacturer's instructions.
2. Note the time of catalyzation or resin mixing (part A + part B, e.g. two part epoxy).
3. Weigh the amount of resin used.
4. After the sample has gelled: check the sample every 5 minutes with a pencil performing pencil indentation. When the resin is no longer able to be "pencil dented", measurement with the Barcol 935 meter can begin. Ensure the needle assembly is perpendicular to the surface and take a reading with the Barcol 935 impressor, reporting the average of the readings.
5. Perform measurements every 5 minutes until the Barcol 935 reaches a measurement of 60-70. When this occurs, switch to the Barcol 934 impressor and continue measuring. During the initial switch to Barcol 934, the needle impressor reading may fade to 0 during the initial readings, make note of this. In the hardness transition range, measurements with both Barcol 935 and Barcol 934 meters should be made (see example analysis).
6. If any resin sticks to the needle, remove and wash the needle to prevent impressor blockage.

Analysis[edit | edit source]

Sample data from the Polynt Composites - Composites Applications Guide ^[1]:

Limitations[edit | edit source]

The described hardness test method does not directly quantify the resin degree of cure as it is defined (see degree of cure page and its definition). The method only provides qualitative information regarding the cure progression with time. If hardness values for the fully cured resin are known ahead of time (or measured previously), the method can provide the user with a quick reference to the resin's relative degree of cure. Otherwise, hardness measurements should be carried out until hardness values plateau as a determination that the resin curing is nearing completion.

The nature of the measurements involved in this test method are best suited for room temperature cure resin systems.

Scope[edit | edit source]

Differential Scanning Calorimetry (DSC) laboratory testing instrument.

Determining the degree of cure (DOC) of a thermoset sample by differential scanning calorimetry (DSC) measurements is the most exact and precise of the methods described on this page. It is achieved by using a DSC laboratory instrument to measure the residual heat of reaction from a sample of the matrix resin to complete any remaining reaction, and comparing it to the resin system’s total heat of reaction for complete curing from the uncured state.

The residual heat of reaction is typically measured by subjecting the sample to a constant linear heating rate, from a low temperature (e.g. -90°C) to a high temperature (e.g. 200°C). Heating is carried out to a sufficiently high enough temperature to ensure complete curing of the sample by the end of the test.

Dynamic tests can be performed in Standard or Modulated mode (if using a modulated DSC instrument - MDSC). The modulated mode adds a sinusoidal heating profile to a linear ramp. The sample undergoes an average increase in temperature but experiences periods of instantaneous heating and cooling. For modulated testing, relatively slow heating rates (e.g. 2-8°C/min) are typically used to allow for sufficient modulations during a thermal event. The modulated mode allows to measure not only the degree of cure but also the glass transition temperature.

Please see the catalogue volume for a list of suppliers selling DSC equipment.

Setup[edit | edit source]

Equipment[edit | edit source]

• Differential Scanning Calorimetry (DSC) laboratory instrument
• Required DSC sample pans, lids, and crimping tool
• High precision scale suitable for measuring 20mg or less of sample (5-10mg of sample is typical)

Test Specimen[edit | edit source]

• Resin sample to be evaluated. DSC sample sizes are small, in the milligram (mg) range. Typically, 5-10mg of resin sample is suitable
• Uncured sample to measure the total heat of reaction

Procedure[edit | edit source]

1. Weigh matrix resin test sample to be evaluated on a high precision scale. Typically, this is in the mg range (5-10mg is typical) for polymer resins. Follow the appropriate scale procedures.
2. Prepare test sample in DSC test pan, place on lid and crimp closed according to DSC manufacturer’s instructions.
3. Perform dynamic heating test on DSC instrument according to the DSC manufacturer’s operating procedure. A standard heating test, or a modulated test can be performed (see Analysis section for discussion).

Analysis[edit | edit source]

If no peak exotherm is recorded by the DSC, it means that the sample was fully cured.

If an exothermic peak was measured by the DSC – determine the heat of reaction by integrating under the obtained curve. Integration of the exothermic peak curve is usually directly offered by the DSC’s software. Alternatively, any suitable mathematics solving computer program can be used. This energy represents the residual heat of reaction, or the remaining uncured portion in the sample prior to DSC testing.

If a modulated dynamic test was performed, the curve to be integrated is the kinetic component of the total heat flow, sometimes referred to as the non-reversing heat flow curve. An advantage of performing a modulated test is that additionally, the resin heat capacity and glass transition temperature can also be simultaneously measured. Modulated testing can only be performed on a modulated DSC (MDSC) instrument, not all DSC instruments have the ability.

The degree of cure of the sample is determined from the following equation\[x=1-\frac{H_{res}}{H_R}\]

Where,

\(x=\) Degree of cure

\(H_R=\) Heat of reaction - total [J/g]

\(H_{res}=\) Heat of reaction - residual [J/g]

Visually, from a DSC characterization of the specific heat flow curve:

By measuring the residual heat of reaction against the total heat of reaction by DSC characterization, the degree of cure can be determined.

To determine the total heat of reaction of the resin system, a dynamic heating test must be performed on an uncured sample of the resin.

Limitations[edit | edit source]

Differential scanning calorimetry (DSC) is a specialized piece of laboratory equipment that may not be accessible to all practitioners. In such cases, measurement and analysis will have to be sub-contracted out to specialist laboratory. Please see the KPC resource guide for a list of laboratories.