Difference between revisions of "Field assisted sintering technology/spark plasma sintering"
(→General principle of FAST/SPS) |
(→General principle of FAST/SPS) |
||
| Line 6: | Line 6: | ||
The tool is heated by a continuous or pulsed direct current with moderate voltages <10 V and high currents in the range from 1 to several 10 kA (depending on the size of the device). Non-conductive powders can also be sintered in good quality via FAST/SPS. Here, the direct contact between the tool and the powder leads to rapid heat transfer and relatively even heating over the entire cross-section of the sample. The heating takes place primarily via thermal conduction. In order to reduce the heat loss through thermal radiation, the die can optionally be thermally insulated, e.g. with a graphite felt. In the standard configuration, heating rates of up to approx. 300 K/min can be achieved in a FAST/SPS device. The high heating rates are one of the main reasons for the fast cycle times, as grain boundary and volume diffusion necessary for mass transport during sintering are activated directly. Due to the thermal mass of the tools, extremely high cooling rates cannot be achieved. Typical cooling rates are around 100 - 150 K/min. It should be noted here that the use of thermal insulation materials further reduces the cooling rates. In addition to the rapid heating, the sintering kinetics are also supported by the applied load. Depending on the type of system and sample size, compaction pressure in the range of 50 - 100 MPa can be achieved with the standard material graphite. Special grades of graphite allow maximum pressures of up to 200 MPa. When using graphite tools, temperatures of up to approx. 2,200 °C can be achieved in FAST/SPS devices. Alternative tools made of highly heat-resistant metals or electrically conductive ceramics enable pressures of up to 400 MPa, but the maximum permissible sintering temperatures are usually significantly lower in these cases. In order to improve the electrical contact between the punches, the die and the sample, a flexible, ideally electrically conductive foil is usually positioned between the punches and the sample. Graphite has also proven to be the standard material for this foil. FAST/SPS systems are usually controlled by programming the temperature-time curve. The measurement of the temperature as a major process parameter is carried out by axially or radially arranged pyrometers or by thermocouples. A direct measurement of the sample temperature is usually not possible. In order to measure the temperature as close as possible to the sample, holes are often drilled in the tools, at the bottom of which the temperature is measured. Furthermore, especially with increasing size of sintered parts and complexity of shape, it is recommended to predict the temperature distribution in the parts using suitable FEM modeling. | The tool is heated by a continuous or pulsed direct current with moderate voltages <10 V and high currents in the range from 1 to several 10 kA (depending on the size of the device). Non-conductive powders can also be sintered in good quality via FAST/SPS. Here, the direct contact between the tool and the powder leads to rapid heat transfer and relatively even heating over the entire cross-section of the sample. The heating takes place primarily via thermal conduction. In order to reduce the heat loss through thermal radiation, the die can optionally be thermally insulated, e.g. with a graphite felt. In the standard configuration, heating rates of up to approx. 300 K/min can be achieved in a FAST/SPS device. The high heating rates are one of the main reasons for the fast cycle times, as grain boundary and volume diffusion necessary for mass transport during sintering are activated directly. Due to the thermal mass of the tools, extremely high cooling rates cannot be achieved. Typical cooling rates are around 100 - 150 K/min. It should be noted here that the use of thermal insulation materials further reduces the cooling rates. In addition to the rapid heating, the sintering kinetics are also supported by the applied load. Depending on the type of system and sample size, compaction pressure in the range of 50 - 100 MPa can be achieved with the standard material graphite. Special grades of graphite allow maximum pressures of up to 200 MPa. When using graphite tools, temperatures of up to approx. 2,200 °C can be achieved in FAST/SPS devices. Alternative tools made of highly heat-resistant metals or electrically conductive ceramics enable pressures of up to 400 MPa, but the maximum permissible sintering temperatures are usually significantly lower in these cases. In order to improve the electrical contact between the punches, the die and the sample, a flexible, ideally electrically conductive foil is usually positioned between the punches and the sample. Graphite has also proven to be the standard material for this foil. FAST/SPS systems are usually controlled by programming the temperature-time curve. The measurement of the temperature as a major process parameter is carried out by axially or radially arranged pyrometers or by thermocouples. A direct measurement of the sample temperature is usually not possible. In order to measure the temperature as close as possible to the sample, holes are often drilled in the tools, at the bottom of which the temperature is measured. Furthermore, especially with increasing size of sintered parts and complexity of shape, it is recommended to predict the temperature distribution in the parts using suitable FEM modeling. | ||
| − | + | [[File:Wiki Keramik FAST SPS Abb 01.jpg|thumb|center]] | |
| − | + | '''Figure 1:''' Heated graphite tool in a FAST / SPS device. | |
| − | |||
| − | |||
== Advantages and limitations of FAST/SPS == | == Advantages and limitations of FAST/SPS == | ||
Revision as of 07:49, 5 August 2021
Contents
General principle of FAST/SPS
Field Assisted Sintering Technology/Spark Plasma Sintering (FAST/SPS) is a low-voltage, current-activated and pressure-supported sintering process that is based on Joule heating (= resistance heating) of the conductive tools (Figure 1) and is characterized by high heating rates and short cycle times. If electrically conductive powders are applied, the powder itself is also heated directly via the Joule effect. The FAST/SPS process is established in the industry and particularly promising when powders are to be sintered, which have a low sintering activity or an unfavorable particle morphology and particle size distribution for conventional pressing and sintering. Furthermore, the method is well suited for the production of composite materials, especially when phases will be combined, which have very different physical properties. Some typical application examples of FAST/SPS technology are presented in Chapter 7. Due to the great flexibility, the short cycle times and the comparatively simple and cost-effective production of tools, research and development is another important field of application for FAST/SPS technology and is widespread there.
In principle, a FAST/SPS device is a mechanical press, which at the same time also forms a high-energy current circuit. The FAST/SPS process is carried out in a conductive tool consisting of two punches and a die. Two additional cones establish the contact with the device's electrodes. The pressing force is also applied via these electrodes by means of a hydraulic pressure cylinder. Figure 2 shows a schematic sketch of such a device. FAST/SPS processes are usually carried out in a vacuum or protective gas to protect the tool and the powder inside the tool from oxidation. Accordingly, the pressing device is located in a water-cooled chamber, in which a moderate vacuum (0.5 - 20 mbar) or a defined protective gas atmosphere (e.g. Ar or N2) can be set. The heating of the tool via the Joule effect requires the use of conductive materials for the punch and the die. The standard material for punch and die is graphite, alternatives to this are introduced in Chapter 4.
The tool is heated by a continuous or pulsed direct current with moderate voltages <10 V and high currents in the range from 1 to several 10 kA (depending on the size of the device). Non-conductive powders can also be sintered in good quality via FAST/SPS. Here, the direct contact between the tool and the powder leads to rapid heat transfer and relatively even heating over the entire cross-section of the sample. The heating takes place primarily via thermal conduction. In order to reduce the heat loss through thermal radiation, the die can optionally be thermally insulated, e.g. with a graphite felt. In the standard configuration, heating rates of up to approx. 300 K/min can be achieved in a FAST/SPS device. The high heating rates are one of the main reasons for the fast cycle times, as grain boundary and volume diffusion necessary for mass transport during sintering are activated directly. Due to the thermal mass of the tools, extremely high cooling rates cannot be achieved. Typical cooling rates are around 100 - 150 K/min. It should be noted here that the use of thermal insulation materials further reduces the cooling rates. In addition to the rapid heating, the sintering kinetics are also supported by the applied load. Depending on the type of system and sample size, compaction pressure in the range of 50 - 100 MPa can be achieved with the standard material graphite. Special grades of graphite allow maximum pressures of up to 200 MPa. When using graphite tools, temperatures of up to approx. 2,200 °C can be achieved in FAST/SPS devices. Alternative tools made of highly heat-resistant metals or electrically conductive ceramics enable pressures of up to 400 MPa, but the maximum permissible sintering temperatures are usually significantly lower in these cases. In order to improve the electrical contact between the punches, the die and the sample, a flexible, ideally electrically conductive foil is usually positioned between the punches and the sample. Graphite has also proven to be the standard material for this foil. FAST/SPS systems are usually controlled by programming the temperature-time curve. The measurement of the temperature as a major process parameter is carried out by axially or radially arranged pyrometers or by thermocouples. A direct measurement of the sample temperature is usually not possible. In order to measure the temperature as close as possible to the sample, holes are often drilled in the tools, at the bottom of which the temperature is measured. Furthermore, especially with increasing size of sintered parts and complexity of shape, it is recommended to predict the temperature distribution in the parts using suitable FEM modeling.
Figure 1: Heated graphite tool in a FAST / SPS device.
