The process of choosing a load cell is often complicated by the fact that each option has its own unique benefits. Truth be told, different load cell applications have their own special requirements. As such, you should discuss load cell capacity requirements with a knowledgeable supplier in advance of making a selection.
The decision you arrive at based on the load cell selection criteria is only one step in the overall process of implementation. Beyond that, you must still ensure you correctly installed and equipped the load cell with the proper instrumentation, otherwise you will not get precise measurements. This load cell selection guide will help you make a more informed choice.
In order to understand your load cell application, you must determine how to conduct the measurement and how the load should be applied. The process of measurement concerns a variety of factors, including:
Load cell measurements help determine the weight of tanks and the performance of durability and break point tests.
Determine the maximum amount of load capacity required for your applications, as well as the necessary minimum.
As you go about determining the load cell capacity requirements of your application, you will need to bear in mind the extraneous factors. To ensure you have the optimal capacity, choose one that exceeds the highest operating load. Moreover, you will need to establish which engineering units will be required for the process. The combined stress caused by extraneous load and moments can put a dampener on the performance of an application.
Consequently, you could seriously compromise the accuracy of an application if you fail to select the proper load cell.
The majority of in-line sensors are ill-equipped for the possibility of extraneous load. For the more high-endurance applications, choose a sensor with an optimal fatigue rating, as specified by the manufacturer.
In order to select the right load cell, determine the needs of your applications. The following questions can help you make that determination:
Another factor is the design of the device in question. Load cell capacity requirements are in part determined by the shape of the device in use, which could include:
When choosing a load cell, make sure you first take these factors into account to ensure that your purchase fits the requirements of the applications.
Another key component of load cell selection criteria is the definition of size requirements. Most specifically, you must determine the needs of your application along the following measures:
To ensure you have sufficient load cell capacity, you will also need to determine the possible variances that could arise, such as:
Finally, you will need to base your choice in part on whether you will conduct the applications in hot or cold temperatures. Likewise, load cell capacity requirements can be determined by whether applications are carried out in submerged settings or out of water. Factors such as the frequency of response and the possible need for special calibration are also matters of interest when you determine your requirements.
At the same time you choose a load cell, be prepared to also select any necessary instruments for the applications you intend to perform. When you pick all the vital pieces at the same time, you can better ensure a system-wide functionality between every component in use.
You should also include system calibration in your order. This will ensure you integrate your instrument and sensor for the same system. Calibration is a vital component to all load cell applications.
of load cell options are preferable in relation to the demands of the setting or application in question. As you learn how to select the right load cell for a particular application, consider your foremost requirements. In general, the performance of a load cell will correlate to the demands of an application as follows:
Load cell selection criteria — or the choice between a strain gage, pneumatic or hydraulic load cell — should largely be determined by the preceding factors.
The most widely used load cells throughout the industrial sector are of the strain gauge variety. People value strain gauge load cells for their durability, stiffness and resonance values. The stain gauge of the load cell is a planar resistor that deforms in connection to the activities of the load cell material. The electrical resistance of the strain gauge changes in form at levels that correlate to the strain.
With the piezoelectric load cell, the deformation is similar to that of the strain gauge load cell. However, the piezoelectric matter generates voltage in response to the changing form of the load cell. The voltage does not serve as a measurement of static values, but nonetheless remains important when the strain undergoes changes. With the conditioning of a charge amplifier, the piezoelectric load cell measures wide ranges particularly well.
The hydraulic load cell works in combination with a cylinder and diaphragm-covered piston. It works like this — place oil in the load cell, and intensify the pressure of the oil by movement the piston makes in response to the load. The transfer of pressure through a hose gauges hydraulic pressure. Due to the lack of electrical parts, a hydraulic load cell can safely be used in hazardous environments.
The pneumatic load cell is made to control the balance of pressure. One side of the diaphragm is exposed to the pressure of air, which travels through the under-nozzle of the load cell. An attached gauge measures the pressure in the load cell.
You can identify S-Beam load cells — alternately known as Z-Beam load cells —by their shape, which resembles the namesake letter. Used primarily in applications that involve tension, S-Beam load cells provide accuracy when the weighing system becomes suspended or hung.
In addition to their high precision, S-Beam load cells enjoy popularity due in large part their affordability and ease of setup. However, S-Beam load cells are made exclusively for in-line applications and tend not to perform accurately with extraneous loads.
You can use beam load cells, named after their rectangular shape, for everything from static weight and dynamic weighing to hopper weighing, silo weighing and tank weighing. Representing a broad category, beam load cells can be subdivided as follows:
Overall, bending beam and shear beam load cells are a low-cost option for a range of industrial applications.
Named for their canister-like shape, canister load cells date back to the very beginning of the strain gauge load cell. In contemporary use, canister load cells have become a common choice for compression applications with capacity requirements of 100,000 lbs. or more.
Applications that involve high precision use the pancake load cell, alternately known as the Low Profile load cell. Pancake load cells come in one of two designs — those with bending beams and those with shear struts. The majority of pancake load cells feature a mounting rig and female center-thread, which makes them suitable for compression and tension applications.
As one of the smaller load cell designs, button load cells received their name from their raised center-button. Due to their compactness, button load cells are one of the most ideal options for applications in narrow, confined settings. Button load cells are especially popular in the medical sector, where operating spaces come at a premium. Applications in the automation industry also benefit from the small design of button load cells.
Alternately known as donut load cells due to their Lifesaver-like shape, thru-hole load cells make an ideal choice for applications that involve the use of clamp force or employ the measurement of bolt force. Designed for high stiffness, thru-hole load cells provide utmost accuracy in press-load and off-center applications.
Consider the following when dealing with adverse loading conditions:
Group Four is a leading supplier of load cells used for applications that involve air and liquid pressure monitoring, compression testing, data acquisition, insertion forces, overload monitoring, peel force measurement, process control, tensile testing, torque measurement and a whole lot more.
At Group Four Transducers, we offer equipment for use in the manufacturing sector for the purposes of safety and quality control. Many organizations use our sensors in applications to take measurements on the pressure that results from physical processes.
For example, a construction company could monitor the amount of pressure that goes into effect during a mechanical lifting operation with one of our sensors, to ensure the crane bearing the weight does not become overloaded. Meanwhile, makers of food products accurately weigh ingredients and ensure the proper balance of additives with our sensors.
At Group Four Transducers, we provide the best customer service in our industry on our full range of items, which include products from competing companies in addition to our own product line. By contrast, most manufacturers only carry their own line, and this forces many customers to go to multiple sources to purchase all the necessary components for a load cell system.
With Group Four Transducers, you can buy everything you need in one purchase. Remember, the best way to choose a load cell is to determine all the necessary components at once so you can buy them at the same time from the same source, as this will ensure compatibility between all the parts to your system.
The capacity of our load cells ranges from 0-10 grams to 0-3 million lbs. Companies around the world use our load cells, including those in the automotive, aerospace, construction, education, energy, manufacturing and medical sectors, in addition to a range of other industries.
Contact Group Four Transducers today for more information on the best load cell for your application or to request a quote. We can find what you are looking for and offer custom solutions that will meet your needs.