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A World First: Monitor and control the temperature of your grinding process with MM 500 control Author: Dr Lena Weigold, Retsch GmbH
An apparently trivial yet potentially challenging point in a sample homogenisation process is to preserve the sample in its original condition. Sample preparation in ball mills, for example, is based on the physical mechanism of impact and friction. These two mechanisms result in heat development which poses a severe problem for temperature-sensitive materials. The MM 500 control is the fi rst laboratory ball mill especially designed to process temperature- sensitive materials.
The MM 500 control monitors and controls the temperature of a grinding process. With its maximum frequency of up to 30 Hz it is a powerful mill for dry, wet and cryogenic grinding processes. Furthermore, the MM 500 control features an innovative concept for sample cooling. The accessible temperature range covers an area from - 100 to 100°C, providing new approaches for sample cooling and cryogenic grinding, see Figure 1. Even sample heating is possible.
Cooling concept
In the MM 500 control, the material is processed in Retsch Screw Lock Jars, which are simply mounted on top of thermal plates for tempering (Figure 2). As the grinding jars are in metallic contact with the thermal plates, heat is effectively transferred from or to the jars. The thermal plates are in turn, tempered by a thermal fl uid.
Figure 1: MM 500 control and its operating temperature range, related to the fi eld of ball mills with water cooling, without cooling or cooling with liquid nitrogen.
Objectives of sample cooling / heating
The MM 500 control offers unique benefi ts to handle temperature-sensitive processes. With this device cumbersome sample precooling or time-consuming grinding breaks are not necessary. Regardless of any specifi c industry, four different objectives are identifi ed that require sample cooling/ heating:
Sample cooling/heating can be required due to various reasons:
1. Preserve substances for analysis: Materials may change their physical or chemical structure, if heated up to elevated temperatures. This means the analyte of interest is not the same as before the sample preparation. Looking at volatile substances or at substances that evaporate at elevated temperatures, also the amount of an analyte can be noticeably modifi ed by the heat development.
2. Embrittling: Ductile and sticky materials must be embrittled for homogenisation in ball mills. Not all samples require a temperature of -196°C as achieved with liquid nitrogen in typical cryogenic mills. The MM 500 control offers a convenient and safe cooling option with high throughput down to temperatures of -100°C.
3. Wet grinding below room temperature: Nano grinding is typically performed in wet grinding processes at high frequencies / rotations per minute. The required high energy input results not uncommonly in temperatures above 80°C. If jars are cooled with a thermal fl uid, no cool-down breaks are necessary during the process and after fi nishing the sample preparation, see example in Figure 4. The temperature at the thermal plates is monitored throughout the whole process. Subsampling to check the fi neness during a process is much easier than in other devices.
Figure 2: Cooling concept based on thermal plates: the sample material is processed in Screw Lock Jars which are mounted on top of the thermal plates.
Technical innovations and advanced design
The technical innovations and the advanced design of the MM 500 control offer completely new features, see also Figure 3.
4. Mechanochemistry: Mechanochemistry and mechanical alloying processes require energy for initiating or intensifying material chemical reactions or the formation of material blends. An active heating of the jar may considerably improve the results of chemical reactions. On the other hand, the temperature regulation of the MM 500 control can also be used to maintain a defi ned low temperature level throughout the whole process and thereby allows to control the formation of chemical derivatives.
Figure 4: Fineness and temperature development in a wet grinding process as a function of time. Jars are cooled with water, which is provided by a chiller set to 4°C and the temperature stays below room temperature.
Figure 3: Key benefi ts and unique features of the MM 50 control.
1. Different confi gurations: For the fi rst time cryogenic temperatures can also be achieved without using liquid nitrogen. The innovative internal tubing system allows to use either liquid nitrogen or another thermal fl uid for sample tempering. Cooling can thus be realised with a standard cryostat or a liquid nitrogen tank.
2. Temperature monitoring: The actual temperatures of the thermal plates are continuously displayed during a grinding process, providing valuable information about the heat development inside the jars.
3. Screw lock jars: Screw lock jars allow easy handling of samples and a high throughput by using two jars simultaneously with a size of up to 125 ml each. Grinding equipment of zirconium oxide and tungsten carbide is also available for cryogenic grinding.
4. Thermal plates: Allowing the indirect sample cooling and heating in a range from - 100 to +100°C.
5. cryoPad technology: If liquid nitrogen is used for tempering, the mill must be extended with the optionally available cryoPad device extension. The cryoPad technology allows for the fi rst time to select and maintain a specifi c cooling temperature for tempering. The accessible area, using liquid nitrogen for cooling, covers a range from -100 to 0°C, in steps of 10. The patented PID (proportional-integral-derivative) system of the cryoPad controls the fl ow of liquid nitrogen through the tubing system and effectively regulates the temperature at the thermal plates.
Application examples
Materials, which are affected by heat development are found in almost every fi eld of application. Agriculture, biology, chemistry, plastics, engineering, recycling, pharmaceutical, food industry, and even geology show a need for sample cooling, see table on the right.
picture material pharmaceutical temperature sensetive substance
e.g. active pharmaceutical ingredients (API)
food (fresh, greasy) e.g. food ingredients, fl avouring, vitamins
plant material polymers cellulose e.g. pesticides, ethereal oils
e.g. plasticisers, polyaromatic hydrocarbons (PAH)
e.g. colour
biological samples e.g. protein, amino acids rocks, soil
e.g. organic matter Conclusion
The Mixer Mill MM 500 control is a true World First: the fi rst high energy laboratory ball mill that allows to monitor and control the temperature during a grinding process. This mill offers new perspectives and possibilities for the homogenisation of temperature-sensitive sample materials, cryogenic grinding or wet grinding processes and in the fi eld of mechanochemistry.
Find out more at:
ilmt.co/PL/Xk0j 56465pr@reply-direct.com
LAB ASIA - APRIL 2022 - ADVERTORIAL
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