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Interface Sensor Mounting and Force Plates

Test and measurement systems are defined by the sensor, instrumentation, and mounting hardware. Mounting considerations are crucial when designing your system. Utilizing best practices in mounting is also extremely important, especially if you are utilizing multi-axis sensors. Deflections in the system can introduce errors and apparent crosstalk into the sensor measurement.

Mounting plates are used to secure sensors during use. The plates should emulate how the sensor was calibrated, so if it was calibrated on stiff plates these characteristics should be duplicated when using the sensor. Plates should be stiff in design, as a flimsy plate secured on corners can introduce errors, such as off-axis loading, due to bending.

Interface mounting plates are made from the best grade alloy and stainless-steel, machined to the tightest specifications, and are designed exclusively to maintain the performance of the sensor in your application.

Interface Mounting Plates Features and Benefits

  • Designed to work with Interface products
  • Made with the highest quality components and processes
  • Created to maintain the specification of the sensors
  • Distributes the load over the foundation of the supporting structure
  • Provides a prepared surface for the load cell
  • Eliminates the requirement for expansion assemblies in most installations
  • Available in standard and custom options

Mounting instructions are specific to each sensor model. Interface offers complete product datasheets and drawings to locate the features for mounting. We also publish mounting instructions for our torque transducer models, as highlighted in our recent Inventive Multi-Axis and Instrumentation Solutions webinar. The instructions we offer include model, material, capacity, mounting holes, threads and dowel pins and pilot specifications, for both live and dead-end use.

Plates must deflect uniformly to minimize local deformation at the mating surfaces. You may need to use a double plate mounting arrangement, also known as a sandwich mount. In this case, they need to be suitably thick. They must be flat and smooth and the same material as the sensor for thermal matching.

Interface offers top plates and bottom plates for load cells. Mounting Plates for Low Profile™ Load Cells are used in the installation of a compression load cell under a weigh bridge, tank, or other structure normally requires that mounting plates be used. The bottom plate is designed to mate with the load cell and is fabricated of mild steel. It distributes the load over the foundation or supporting structure and provides a prepared surface for the load cell.

The top plate distributes the load to the weighing structure and provides a hard surface for the load button. The top plate will move on the button due to thermal expansion, load shifting, wind loading, and other side loads. The high side load capacity of the Interface load cell eliminates the requirement for expansion assemblies in most installations. Mounting plates are suitable for compression loads only; they will not properly support a universal load cell used in tension.

Interface has recently introduced force plates. Interface Force Plates are a system of multiple multi-axis sensors mounted between two plates. They are ideal for larger capacities than single 6-Axis sensors and can react high moments. Results dependent on characteristics of the plates and other system components and for load introduction and bigger sensors, you should consider in-situ calibration.  Force plates are used for applications such as robotic arms. When secured at the base of the arm, the four sensors are providing feedback during use.

You can learn more about force plates and mounting plates for multi-axis sensors in our latest webinar. Learn more by watching the multi-axis webinar here.

Interface offers mounting plates in our accessories product line. For custom applications, such as our force plates or multi-axis mounting plates and systems, contact our Application Engineers today.

Additional Resources

3A Mounting Instructions

 

New Interface White Paper Highlights Turning an Active Component into a Sensor

The most common uses of force measurement in OEM (original equipment manufacturer) applications are when a force sensor is designed into a product that will be produced at mid to high volumes and provides real-time force feedback on certain product functions in use. Utilizing sensors as a feature enables data acquisition over time to monitor forces and understand how those forces effect product efficiency, safety, quality or all of these performance metrics. This ultimately is used to design a better product, in the current state and for future enhancements or to know when a product is performing best or risks breaking down.

Did you know that there is another application of force sensors in OEM applications that is playing a large role in the factory of the future? This is when we turn an active component into a sensor and use that data to create automated actions. This solution is used when there is a desire to take a moving component within a system and make it smarter, ultimately allowing it to make data-based decisions on its own.

For example, the manufacturing industry is using force sensors on machines within a production line that are responsible for picking components up for visual inspection. The sensor is integrated into the grabbing component and can tell the machine the exact force to use when picking up the component as not to damage it. This is a critical capability when dealing with expensive and delicate components that can break under too much force. In the past, a force measurement sensor would have been used only to test this functionality. When the sensor is designed directly into the machine, the user can both test beforehand and monitor and automate processes in real-time.

The need for this type of capability is growing rapidly amongst manufacturers across a wide variety of industry including aerospace and defense, industrial, medical, automotive, industrial automation, assembly and more. To further outline the potential for these types of solutions, Interface developed a new white paper that details  how sensor solutions for OEMs work with specific examples of the benefit of turning an active component into a sensor.

Included below is a brief intro to the recently released white paper. Get your copy by clicking on the link here. Additionally, if you’re interested in learning more about Interface solutions for OEM applications go here, or call us to speak to our OEM application experts at 480-948-5555. Ready to get started, let us know how we can help here.

WHITE PAPER EXCERPT

OEM SOLUTIONS: TURNING AN ACTIVE COMPONENT INTO A SENSOR

The age of industrial automation and big data is upon us. Manufacturers that fall behind in equipping their facilities and products with innovation that allows for automated processes, remote monitoring and better efficiency through technology, will quickly fall behind. This is due to the fact that automation helps to significantly improve process quality because it eliminates human error. It also creates long-term cost savings by speeding up several processes, or by helping to monitor products in use and in real-time to optimize performance and stability over time through better data collection.

Get your copy of the white paper to read more.

Special note, contributors to the white paper are Interface and sensor engineering experts, Brian Peters and Rob Fuge.

Additional Resources for OEM

Interface is a Critical Solutions Provider for OEMs

Making the Case for Custom Solutions Webinar Recap

 

Interface Load Cell Indicators

At Interface, our claim to fame is that we offer the most accurate and reliable force measurement devices on the market, from load cells to torque transducers and everything in-between. However, no test is complete without the system used to gather the data to evaluate performance results. That’s why we provide a wide variety of instrumentation solutions that include signal conditionersoutput moduleshigh speed data loggersportable load cell indicators, and weight indicators to complete any testing system.

Among the Interface instrumentation products, the most frequently purchased with a force measurement devices are our load cell indicators in various models including handheld, digital, wireless, multichannel, programmable, output modules, analog and bidirectional.

What is a load cell Indicator?

A load cell indicator is a high-accuracy device connected to the output of a load cell to amplify and display the value of the measured load force and weight. Load cell indicators are often needed where the force, load, or weight measurement needs to be visually displayed for the user and displaying the results on a PC is not feasible or desired in the testing environment. For example, testing in the field or confined spaces can make it impossible to connect directly to a PC. In these situations, indicators are used to quickly review and capture force data in real-time.

A few key benefits of load cell indicators include that they provide stable excitation voltage and converts force measurement sensor signals to a digital display. Commonly available features include analog or digital output, selectable digital filtering, peak and valley monitoring and set-point outputs. Additionally, each load cell indicator can be used to connect to four (or more) digital load cells and can display individual readings or the sum of all connected load cells.

Need a load cell indicator?

Interface offers a wide variety of load cell indicators in multiple configurations. Interface indicators come in single to multi-channel weight transmitters and can be found in handheld and portable designs. Things to consider when selecting an indicator are internal sample rate and update rate of the output. A few of our most popular indicators include:

9890 Strain Gage, Load Cell, & mV/V Indicator

Model 9890 is a powerful multipurpose digital load cell meter ideal for weight and force measurement applications. With a max current of 350 mA at 10 V, it can support up to 12 load cells making it perfect for multipoint weight measurement purposes. The dual-scale capability allows for displays in two different units of measure. See a demonstration video here.

9320 Battery Powered Portable Load Cell Indicator

Model 9320 is a bipolar 7-digit handheld meter featuring two independently scalable ranges, peak and valley monitoring, display hold, mV/V calibration, and a power save feature. Typical battery life exceeds 45 hours of continuous use and 450 in low power mode. IEEE1451.4 TEDS Plug and Play compliant.

482 Battery Powered Bidirectional Weight Indicator

Model 482 is battery powered, bidirectional, and comes in a NEMA 4X stainless enclosure. Standard options include 523,000 internal counts, 0.8-inch LCD 6-digit display and a measurement rate that goes up to 40 Hz. Available options include analog and relay outputs.

1280 Programmable Weight Indicator and Controller

The Interface 1280 Series programmable digital weight indicator with color touchscreen, web server view and multiple protocol types delivers uncompromising speed for today’s operations and expansive options for tomorrow’s requirements.

INF4-Ethernet IP Weight Transmitter and Indicator

The Interface INF4-Ethernet IP weight transmitter and indicator has a six-digit red LED display (8 mm height), space-saving compact design, four buttons for the system calibration, and a six-indicator LED.

See all the indicator options here.

Load Cell Indicator Application Note

The application note below provides an example of the benefit of a load cell indicator in real-world use within the medical industry.

A pharmaceutical tablet producer wanted to monitor the forces applied by the tablet forming machine to understand the relationship between raw material, die set, forming force, and motor-cycle speed. The goal was to improve productivity and efficiency of the tablet forming process while reducing losses, such as cracked tablets or voids, by adding a dimension of feedback that could be used to assign specific press adjustment criteria for given inputs.

An Interface Model WMC Sealed Stainless Steel Mini Load Cell (10K lbf Capacity) was mounted in the section of the downward press bar. The machine was modified to accomplish this. The load cell was then connected to a Model 9320 Portable Load Cell Indicator to collect the needed data.

The indicator was selected as the data collection device because a laptop could have interfered with the test cycle due to space restrictions. The output of the load cell was connected to the 9320 Portable Load Cell Indicator and set aside so that the cable did not interfere with the cycle and no snagging would occur. A cable tie was used to stow aside the cable and to ensure there was enough clearance for the entire cycle.

After analyzing the data, the tablet producer was able to quantify adjustment levels by monitoring which forces produced the most optimal results for a given cycle speed, die set, and raw material. Productivity and efficiency were greatly improved by the enhancement of the data feedback.

To learn more about Interface load cell indicators and for a complete list of products, you can download our instrumentation brochure here. You can also read more about instrumentation options in test and measurement in this post.