RC1mx and HFCal

RC1mx HFCal™

Ensure Safety by Design

World-leading reaction calorimeter for process safety and scale-up.

Temperature Range: -70 °C – 300 °C
Operating Volume: 100 mL – 22 L

optimax pg thumbnail

Optimax HFCal™

Detect Non-Scalable Conditions

For fast and efficient safety studies for process characterization and scale-up.

Temperature Range: -40 °C – 180 °C
Operating Volume: 60 mL – 1,000 mL

EasyMax 402 HFCal

EasyMax 402 HFCal™

Calorimetry for Safety Screening

Designed for fast and efficient safety screening and characterization of chemical processes early in development.

Temperature Range: -40 °C – 180 °C
Operating Volume: 40 mL – 400 mL

EasyMax 102 HFCal

EasyMax 102 HFCal™

Calorimetry for Safety Screening

Designed for fast and efficient safety screening and characterization of chemical reactions at small scale.

Temperature Range: -40 °C – 180 °C
Operating Volume: 30 mL – 100 mL

EasyMax 102 HFCal

EasyMax 102 LT HFCal™

Developed for Low Temperatures

Facilitates low temperatures at the push of a button. Special purging of the reactor zone prevents icing.

Temperature Range: -90 °C - 80 °C
Operating Volume: 30 mL – 100 mL

What is reaction calorimetry?

Reaction calorimetry measures the heat released from a chemical reaction or physical process and provides the fundamentals of the thermochemistry and kinetics of a reaction.

The information obtained is essential to describe the heat release of a chemical reaction over time, and to safely transfer it from lab to plant.

Reaction calorimetry uncovers unexpected behavior and makes any scalability issues visible and quantifiable. It also helps to identify issues related to heat and mass transfer or mixing, and allows the determination of the correct temperature, stirring, or dosing profile of a given reaction or process. The information obtained is subsequently used to evaluate a process's risk, scalability, and criticality.

Reaction calorimetry data is used to characterize, optimize, and understand process parameters in a controlled, accurate, and reproducible environment, enabling safe scale-up and transfer into manufacturing.

What is heat flow calorimetry?

what is heat flow calorimetry

what is heat flow calorimetry

Heat flow calorimetry is the simplest and most robust method for determining the heat released by a chemical reaction or physical process. It is supported by all METTLER TOLEDO reaction calorimetry workstations. Heat flow calorimetry is highly sensitive and applicable under most conditions, and it offers excellent repeatability.

The heat flow calorimetry principle is based on measuring the temperature difference across the reactor wall, which is then converted into a heat flow by measuring its heat transfer coefficient.

The heat transfer coefficient depends on the type of chemistry, reaction conditions, and the reactor material and is determined using a reference electrical heater.

To get real and accurate data, each workstation and reactor is provided with a Thermal Analysis (Ta) model that corrects the heat flow through the reactor walls, considering the thermal conductivity and thickness of the reactor wall, the thermal resistance of the reaction mass film, and the thermal resistance of the oil film.

The method of heat flow calorimetry is applicable on both small and large scales and is the basis for all chemical process development projects, process scale-up, and chemical process safety investigations.

What is the value of reaction calorimetry?

reaction calorimetry graph

Reaction calorimeters allow the efficient and safe development of processes at scale.

As a reaction is scaled from lab to plant, scalability problems may suddenly emerge for various reasons. In the worst case, unidentified reaction risks may lead to a runaway reaction followed by an explosion. The causes of thermal incidents are often attributed to:

  • Lack of understanding of the chemistry or the thermochemistry of a process
  • Inability to remove heat
  • Bad or poorly understood mixing behavior
  • Human factors

Incidents can be avoided by determining the relevant data at lab scale. The lab work is performed under process-like conditions using reaction calorimeters so that the results can be directly applied to larger-scale operations.

Reaction calorimetry provides a high level of process understanding so that the necessary procedures can be performed routinely, robustly, and to the required quality standards.

How can you obtain accurate and precise calorimetric data under any conditions?

Accurate and precise heat flow data is essential for transitioning from lab to plant. A high-performance heating and cooling system combined with a sensitive temperature measurement and control system is a prerequisite to obtaining accurate and precise heat information about a chemical process. This includes details about the heat of the reaction, the total heat flow balance, the mass and heat transfer, and the specific heat of the reaction mass.

The total heat flow balance of a chemical process itself includes a variety of thermal effects, such as the accumulation of heat, heat exchange due to reactant or solvent additions, heat due to changing viscosity, heat loss, etc.

For reactions that are run under changing temperature conditions, heat accumulation becomes an important factor in the calculation of the heat of the reaction (heat released as a function of time). In this case the correction from isothermal to non-isothermal temperature control is essential and the Thermal Analysis (Ta) model plays an extremely important role.

METTLER TOLEDO reaction calorimeters and iControl software suite use sophisticated calculation algorithms. These take into account the dynamic behavior of the reactor wall, the heat capacities of the vessel, and the reactor inserts – providing calorimetric data of maximum accuracy and precision.

What is heat of reaction?

The heat of reaction, or reaction enthalpy, is the energy that is released or absorbed during a chemical reaction. When reactants are transformed into products, it describes how the energy content changes. While there are endothermic (heat absorbing) and exothermic (heat releasing) reactions, the majority of reactions carried out in the chemical and pharmaceutical sectors are exothermic. The heat of reaction is one of the thermodynamic characteristics that is utilized in chemical research, scale-up, and safety to scale processes from the lab scale to production, among other things.

Learn more about heat of reaction and reaction enthalpy.

Can I connect my reaction calorimeter to third party accessories?

Yes! The Easy Control Box (ECB) accessory (purchased separately) extends your reaction calorimeter automated control and data capture of third-party devices, including sensors, dosing, and sampling solutions.

ECB provides dosing control capabilities and easily connects commercially available pumps and balances for automated pre-programmed gravimetric or volumetric dosing.​ The accessory has plug-and-play measure functionality with SmartConnect Technology Sensors. Control elements are automatically recognized making the reactor system configuration a simple task.​ 

Learn more about Easy Control Box (ECB).

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