Thermal-Mechanical Physical Simulation System
The result is a system unequaled for physical simulation and thermal-mechanical materials testing.
The Gleeble 3800 Thermal System
The direct resistance heating system of the Gleeble 3800 can heat specimens at rates of up to 10,000°C/second, or can hold steady-state equilibrium temperatures. High thermal conductivity grips hold the specimen, making the Gleeble 3800 capable of high cooling rates. An optional quench system can achieve cooling rates in excess of 10,000°C/second at the specimen surface.
Thermocouples or an optional infrared pyrometer provide signals for accurate feedback control of specimen temperatures. Because of the unique high speed heating method, Gleeble systems typically can run thermal tests 3 to 10 times faster than conventional furnace equipped machines.
Induction Heating Option: Gleeble 3500-GTC and 3800-GTC systems, including the Gleeble 3800-GTC-20/20, can be supplied with an optional Induction Heating system to complement the industry leading performance of the well-known Gleeble direct resistance heating technology.
Induction heating is suited for use in uniaxial compression testing (flow stress) where it can provide a uniform temperature across the specimen from anvil to anvil. Induction heating can also be used in tensile testing. The system allows the user to select either induction or resistance heating based on the needs of each specific test. The full capability of the high speed Gleeble direct resistance heating system is still maintained, allowing heating rates up to 10,000ºC/second when using direct resistance heating. The two heating systems are both integrated to work on the Gleeble and software can be used to select which heating system is used in each test.
Click here to learn more about the Gleeble Induction Heating option.
The Gleeble 3800 Mechanical System
The Gleeble 3800 mechanical system is a complete, fully integrated hydraulic servo system capable of exerting as much as 20 tons of static force in compression or 10 tons in tension, with an available upgrade that enables up to 20 tons in tension. Displacement rates as fast as 2000mm/second can be achieved. LVDT transducers, load cells, or non-contact laser extensometry provide feedback to insure accurate execution and repeatability of the mechanical test program.
The mechanical system allows the operator to program changes from one control mode to another during any given test. This capability provides the versatility that is necessary to simulate many thermal-mechanical processes. The program can switch between control variables at any time and as often as required during the test. Control modes that are available include stroke displacement, force, various extensometers, true stress, true strain, engineering stress, and engineering strain.
Gleeble 3800-GTC Specifications:
|Force||Maximum Compressive Force||20 Metric Tons|
|Maximum Tensile Force - Gleeble 3800-GTC (Standard)||
10 Metric Tons
|Maximum Tensile Force - Gleeble 3800-GTC-20/20||20 Metric Tons|
|Stroke||Maximum Stroke Distance||125 mm|
|Maximum Stroke Rate||2000 mm/sec|
|Minimum Stroke Rate||.001 mm/sec|
|Temperature Control||Maximum Temperature||3000 °C|
|Maximum Heating Rate||10000 °C/sec|
|Maximum Quenching Rate||10000 °C/sec|
|Maximum Specimen Size||20 mm diameter|
Gleeble systems are available in several models, each with a wide variety of available options and configurations. This flexibility allows the tailoring of a Gleeble system to meet your exact testing requirements. DSI offers a range of measurement systems including contact and non-contact options. Click here to learn more about some of DSI's most popular measurement options.
The Gleeble 3800 Digital Control System
The heart of the Gleeble 3800 is the Series 3 Digital Control System. It provides all the signals necessary to control thermal and mechanical test variables simultaneously through the digital closed-loop thermal and mechanical servo systems. The Gleeble 3800 can be operated totally by computer, totally by manual control, or by any combination of computer and manual control needed to provide maximum versatility in materials testing.
The environment for computer control of the Gleeble 3800 consists of a Windows based workstation and powerful embedded processor in the control console. The Windows workstation offers a flexible industry-standard multi-tasking Graphical User Interface for creating simulation programs and analyzing the resulting data, as well as creating reports and presentations.
The embedded processor executes test and simulation programs and collects data under the control of the Windows program. This division of labor offers the full power of the workstation to the user while tests are running, enabling the operator to create new tests and analyze data while the machine is actively executing tests or physical simulations.
The Gleeble 3800 has a full set of software tools available. The operator can create tests on the workstation through a number of programming options, including QuikSim Software, a spreadsheet-like, fill-in-the-blanks software that describes each action in a test sequence in order and duration. QuikSim allows arbitrary programming of waveforms for both thermal and mechanical systems. Other options for creating more elaborate tests include Deformation Control Software and Gleeble Script Language.
In designing the operator interface for the Gleeble 3800, DSI engineers recognized that highly flexible control is essential for machine performance. Thus every aspect of the 3800 control system can be controlled via computer and set up in advance in the program. To make the system even more flexible and allow easy, convenient manual control of the system at any time, the Gleeble 3800 includes a freestanding control console with 10 Virtual Panel Meters (VPMs). Each of these VPMs includes a control knob and data readout and can be software configured to control whatever part of the system the operator requires. As a result, the operator has total flexibility in manual control of the system, yet sacrifices none of the power and convenience of computer control when that is a better option. Prewritten test programs can be run with no modifications or, if desired, the VPMs can be used to adjust the program while the test is in progress.
Once a test or simulation has been completed, the results are automatically loaded into Origin software, a powerful and flexible data analysis package included with every Gleeble 3800 System. Origin provides many built-in mathematical functions for analyzing data as well as the LabTalk language which can be used to automate the repetitive analyses tasks typical of a comprehensive simulation or testing program. Origin can be set up to load data from each test and immediately display any number of plots, allowing a quick and easy review of each test. Origin produces colorful, publication-quality graphs and charts.
Add Capabilities with Mobile Conversion Units (MCUs):
Thermal Cycles and Heat Treatments: Many different grips are available to support uniform temperature zones and a variety of specimen configurations. Other grips can be used to provide thermal gradients in the specimen for weld HAZ and process simulation.
ISO-T Flow Stress Compression Testing: ISO-T flow stress compression anvils provide a uniform temperature distribution throughout the compression specimen during single- and multiple-hit deformation tests.
Melting & Solidification: Melting and solidification can be performed in-situ. Thermal and mechanical testing of the as-cast structure can then be performed.
Strain Induced Crack Opening (SICO) Procedure: A Gleeble exclusive, the SICO procedure is a quick and cost-effective method for thermomechanical process optimization.
Hot/Warm Deformation: Plane strain compression test. In single- or multiple hit compression tests, strain and strain rate are controlled separately yet synchronously using the optional Hydrawedge®.
Strip Annealing Process Simulation: Both batch and continuous annealing processes can be simulated using a strip annealing jaw system.
For additional information and customization options,
please contact us at email@example.com or +1 (518) 283-5350.