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Static Load Cells (500 N to 600 kN)
2580 Series
The Instron 2580 Series static load cells are high-precision force transducers optimized for use with 5900 and 6800 Series universal testing systems, capable of measuring loads across a wide range (up to ±600 kN) with accuracy to 0.5 % of reading and sensitivity down to 1/1000th of full scale. Temperature-compensated and calibrated on equipment traceable to international standards, they have automatic recognition with an electronic serial number and support electronic calibration, while offering overload protection (up to 150 % without damage, 300 % without mechanical failure). The 2580’s design delivers high stiffness and reliable alignment under load—making it a robust choice for tension, compression, cyclic, and reverse stress testing in materials and components.
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High Precision Compression Type Load Cell
IR
A high-precision compression-type load cell is a sensor that accurately measures compressive (pushing) forces, designed for applications requiring very tight accuracy and reliability. It works by converting a downward force into an electrical signal, often using strain gauges to measure deformation, and is used in demanding fields like calibration, manufacturing, and medical equipment.
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Test Cell Controller
RAPID
The Rapid II Test Cell Controller is an integrated, multi-loop control and data acquisition system for test cell applications, designed to provide maximum performance at an affordable price. Rapid II combines the latest in digital control technology with off-the-shelf hardware to produce one of the industry's most powerful, flexible and advanced controllers at a cost-effective price. This high-speed, 4-channel PID controller includes ample I/O to act both as a system controller and a data acquisition system, reducing overall system cost and complexity. Designed for integrators, OEMs, and DIYers, these systems can be configured to fit your needs with little upfront costs and minimal risk while benefiting from a stable, powerful platform.
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Ancillary Test Cell Products
In addition to our innovative and industry leading AccuDyne AC Dynamometers and DynoLAB Test Automation Systems, SAKOR fully integrates a complete range of ancillary products and subsystems necessary for an advanced test cell. Examples include:*Combustion air consumption measurement and conditioning subsystems*Exhaust handling systems*Fuel consumption measurement and conditioning subsystems*Coolant and oil conditioning systems*Throttle actuators*Spark/Fuel controls*Combustion analysis systems*Complete exhaust emissions analysis systems (per 40 CFR 1065 regulations)*Sound attenuating (up to STC 52) test cell enclosures with several fire suppression options*Process water evaporative cooling tower
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Your Automated Microscope For Live Cell Imaging
ZEISS Celldiscoverer 7
Combine the ease of use of an automated microscope with the image quality and flexibility of a research microscope. Whether working with 2D or 3D cell cultures, tissue or small model organisms, you will acquire better data in shorter times with this automated live cell imaging platform. Add LSM 900 with Airyscan 2 to gently image dynamic processes with highest framerates in superresolution.
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Fuel Cell Test Systems
Fuel Cell Test System is a complete test station for operation and measurement of PEM/DMFC fuel cells.
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BNC (M) To Stacking Pin Tip Plugs
3901
BNC (m) to stacking pin tip plugs. Miniature banana plug springs are gold plated Beryllium Copper for excellent electrical connection.
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Electric Vehicle Battery Cell Tester
MCV
The MCV is a low-current life cycle test system for development of primary and rechargeable batteries in various chemistries. Operating from a common microprocessor, multiple circuits in the MCV module can run individual test programs. Additionally, the MCV is designed and built for ease of maintenance and service. The modular construction means that most subassemblies, large or small, remove easily for service outside the cabinet and fast replacement.
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Load Cells
The heart of each weighing system is a load cell. Load cells are mechanical components which act as force sensors by employing strain gages to provide an electrical output proportional to the applied force. Typically the electrical output is either analog (voltage or current) or digital. Load cells have specific mechanical packaging and sensing orientation to fit into electronic scales, and testing and monitoring systems. Load cells can be used for tension, compression, and/or shear measurement.
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Through Hole/ Donut Load Cell Compression Only
THA SERIES
Our THA Series through hole donut load cells offer an outside diameter of 1.00 inches and up to two different through hole diameter options per capacity range. These load cells are manufactured from heat treated 17-4 ph stainless steel. The sensing element incorporates bonded foil strain gages of the highest quality and are sealed for protection against most industrial environments.
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Load Cells
A load cell is a sensor which transforms the load or force applied to it into an electrical signal. Load cell sensors are based on the strain-gauge principle i.e. a sensor whose resistance varies with applied force. They are the most widely used as load transducers in all areas of weight measurement from retail scales, the process industry and medical applications.
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Solar Cell Characterisation
The PVE300 permits the determination of device spectral responsivity (from which may be determined EQE), and, having performed measurements of sample reflectance (and transmittance where required) the determination of IQE.
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Solar Simulator for Multijunction Solar Cells
For series connected multijunction cells, at a given spectrum (e.g. AM 1.5 or AM 0 for space solar cells), one of the cells will limit the current in the series connection of cells. All solar simulators deviate from the true AM 1.5 spectrum, and they are only classified in wide spectral bands (100nm width). So even for class A or A+ solar simulators, it can easily happen that the bandgaps of the multijunction cells are such distributed that the 'wrong' cell will limit the current, if a solar simulator with fixed spectrum is used. In the 70s and 80s, when these measurements were first developed, intercomparisons showed deviations of cell efficiency in fixed spectrum solar simulators of more than 40%.
