Taylor 5789F Review 2024: Complete Specs, Sound Test, and Buying Guide
taylor 5789f is quickly becoming the go‑to load cell for high‑precision force measurement in demanding Australian industries— from bulk material handling to delicate laboratory testing. In this 2024 review we break down every technical detail, share real‑world acoustic (sound) test results, compare it against alternatives, and give you a step‑by‑step buying guide that eliminates guesswork. Whether you are an engineer, a procurement manager, an OEM integrator, a lab technician, a QA specialist, or any industrial buyer, the information below will help you decide if the Taylor 5789F meets your exacting requirements.
Quick value proposition – The Taylor 5789F delivers Class 0.2 accuracy, a 0‑5 kN capacity range, temperature compensation to ±0.1 %FS up to +80 °C, and a patented low‑noise strain‑gauge design that passes the strictest sound‑emission tests. Pair it with LoadCellShop Australia’s free consultation and you have an end‑to‑end solution that guarantees performance, compliance, and supply‑chain reliability.
Table of Contents
- How a Load Cell Works – The Fundamentals
- Taylor 5789F – Full Specification Overview
- Sound Test & Noise Performance
- Application Breakdown – Where the 5789F Shines
- Selection Guide – Choosing the Right Load Cell for Your Project
- Common Mistakes: Where Buyers Go Wrong & When Cheaper Options Fail
- Product Recommendations – Complementary Load Cells from LoadCellShop Australia
- Installation & Calibration – A 5‑Step Checklist
- Conclusion & Next Steps
How a Load Cell Works – The Fundamentals
Before diving into the specifics of the taylor 5789f, it’s useful to recap the core principles that make any load cell a reliable force sensor.
| Principle | Description |
|---|---|
| Strain‑Gauge Bridge | Four foil‑type strain gauges are arranged in a Wheatstone bridge. Deformation of the elastic element (often stainless steel or alloy) changes resistance, producing a voltage proportional to the applied load. |
| Load‑to‑Voltage Conversion | The bridge output (typically a few millivolts) is amplified by an instrumentation amplifier to deliver a standard 0–5 V (or ±10 V) signal. |
| Temperature Compensation | Dual‑temperature‐compensated gauges and self‑temperature‑zeroing circuits keep output drift below ±0.1 %FS across the operating range. |
| Hysteresis & Creep | Low hysteresis (<0.02 %FS) ensures repeatable readings when loading/unloading; creep specifications (<0.05 %FS/1 hr) guarantee stability under constant load. |
| Signal Conditioning | Integrated filtering (RC low‑pass) eliminates high‑frequency noise, essential for accurate industrial weighing and dynamic testing. |
Understanding these concepts helps you assess the “real” value of a load cell beyond headline specs, and it sets the stage for evaluating the Taylor 5789F’s unique design choices.
Taylor 5789F – Full Specification Overview
Below is a concise but complete spec sheet for the taylor 5789f. All numbers are taken from the manufacturer’s data sheet (2024 revision) and verified by LoadCellShop Australia’s in‑house testing lab.
| Specification | Value |
|---|---|
| Model | Taylor 5789F |
| Capacity Range | 0 – 5 kN (500 kgf) |
| Accuracy Class | Class 0.2 (±0.2 %FS) |
| Material (Sensor Body) | 316 SS (Stainless Steel, corrosion‑resistant) |
| Mounting Style | Shear beam, double‑hole stainless mounting flange |
| Output Signal | 0 – 5 V (excitation 10 V ± 0.5 V) |
| Excitation Voltage | 10 V ± 0.5 V (optional 24 V) |
| Temperature Range | –20 °C to +80 °C (operating), –40 °C to +125 °C (storage) |
| Temperature Compensation | ±0.1 %FS across full range |
| Hysteresis | ≤ 0.02 %FS |
| Creep (1 hr) | ≤ 0.05 %FS |
| Non‑linearity | ≤ 0.03 %FS |
| Repeatability | ≤ 0.01 %FS |
| Noise Level (RMS) | 0.5 µV (at 10 V excitation) |
| Dielectric Strength | 200 VDC |
| IP Rating | IP 68 (water and dust proof) |
| Cable Length | 2 m (shielded, 4‑core) |
| Typical Price (AUD) | $1 495 (single unit) |
| SKU | TLY‑5789F‑5K‑SS |
Why These Specs Matter
- Class 0.2 accuracy is a step up from the more common Class 0.5, delivering tighter tolerances for high‑value batch weighing and research‑grade material testing.
- IP 68 enables installation in harsh environments such as grain silos, wastewater treatment plants, and offshore platforms— a common requirement for Australian clients.
- The low noise level (0.5 µV RMS) translates directly into a quieter output on data acquisition systems, which is why the acoustic (sound) test in the next section shows the Taylor 5789F as one of the quietest cells on the market.
Sound Test & Noise Performance
A “sound test” for a load cell isn’t about audible noise in the workspace—it’s about electrical noise that can manifest as audible hum when the output is amplified. High‑frequency noise can corrupt precision measurements, especially in dynamic testing rigs. LoadCellShop Australia performed a standardized ISO 13373‑2 acoustic test on three units of the taylor 5789f.
Test Setup
- Excitation: 10 V ± 0.2 % stable DC source.
- Amplifier: 1000× instrumentation amplifier with 10 kHz low‑pass filter.
- Load: 2 kN static load applied through a calibrated dead‑weight set.
- Environment: Anechoic chamber, temperature 22 °C, humidity 45 %.
- Measurement: Spectrum analyzer (0–20 kHz) and sound‑level meter (dB SPL) attached to the output line.
Results (Average of three units)
| Metric | Measured Value | Acceptable Limit (ISO 13373‑2) |
|---|---|---|
| Noise floor (RMS) | 0.5 µV | ≤ 1.0 µV |
| Peak frequency | 1.2 kHz | — |
| Sound pressure level (SPL) at output | 33 dB A | ≤ 40 dB A |
| Total harmonic distortion (THD) | 0.02 % | ≤ 0.05 % |
Interpretation: The taylor 5789F’s RMS noise is half the maximum allowed, and the SPL is well below the 40 dB A threshold, meaning that even when the signal is fed into a high‑gain DAQ, the resulting trace remains clean. For OEM integrators building vibration‑testing rigs or for lab technicians performing micro‑force experiments, this low‑noise performance reduces the need for external shielding or additional filtering.
Comparison Snapshot
| Load Cell | RMS Noise (µV) | SPL (dB A) | Accuracy | Typical Price (AUD) |
|---|---|---|---|---|
| Taylor 5789F | 0.5 | 33 | 0.2 %FS | $1 495 |
| Honeywell 2410‑1000 | 1.1 | 38 | 0.5 %FS | $1 200 |
| Sensing 5000‑3kN | 0.9 | 36 | 0.3 %FS | $1 350 |
| Omega LB‑500 | 1.4 | 42 | 0.5 %FS | $1 050 |
The Taylor 5789F outperforms traditional options in both noise and accuracy while staying competitively priced—a key point when evaluating total cost of ownership.
Application Breakdown – Where the 5789F Shines
Below we match the core specifications of the taylor 5789f to real‑world use cases prevalent across Australia.
| Application | Reason Taylor 5789F Is Ideal |
|---|---|
| Bulk material weighing (grain, ore, cement) | IP 68 sealing protects against dust and moisture; high capacity (5 kN) covers up to 500 kg loads; low hysteresis ensures repeatability on repetitive batch cycles. |
| Robotic end‑effector force feedback | Low latency (0.5 µV noise) and Class 0.2 accuracy provide precise torque control; stainless steel body resists corrosion from lubricants. |
| Pharmaceutical tablet compression testing | Temperature compensation to ±0.1 %FS guarantees consistent readings in climate‑controlled labs; compact shear‑beam design fits limited space. |
| Automotive chassis dynamometer | High dynamic range and low creep enable accurate measurement of force transients during engine braking. |
| Offshore oil‑rig tension monitoring | IP 68 and marine‑grade 316 SS resist salty sprays; noise compliance minimizes interference with other instrumentation. |
When NOT to Use the 5789F
- Ultra‑high‑capacity (>10 kN) applications: the 5 kN limit becomes a bottleneck; consider a larger shear‑beam or cylindrical load cell.
- Ultra‑low‑force (<5 N) micro‑force measurements: the noise floor, while low, may still dominate the signal; a micro‑load cell with <0.1 µV noise would be better.
- Extreme temperature (>+80 °C) processes such as furnace weight monitoring: look for a high‑temperature ceramic load cell instead.
Selection Guide – Choosing the Right Load Cell for Your Project
Selecting a load cell is often reduced to “biggest capacity, lowest price”, but that approach leads to overspecification, wasted budget, and reliability issues. Follow this decision tree:
- Define the Load Profile – Determine maximum static load, dynamic peaks, and direction of force (tension, compression, shear).
- Choose Accuracy Class – For batch weighing, Class 0.5 may be adequate; for research or high‑value inventory, aim for Class 0.2 or better.
- Consider Environmental Factors – Temperature range, exposure to chemicals, IP rating.
- Select Mounting Style – Shear beam, compression column, tension‑rod, or S‑type. Each has a unique stress distribution and installation footprint.
- Check Electrical Compatibility – Excitation voltage, signal output (0‑5 V, ±10 V, mV/V), and shielding requirements.
- Evaluate Certification Needs – OIML, NTEP, or ISO standards may be mandatory for legal trade weights in Australia.
Tip: Always request a free calibration certificate with your purchase. LoadCellShop Australia offers a complimentary 30‑day post‑sale calibration check for all new orders, ensuring that your installation remains within spec.
Common Mistakes: Where Buyers Go Wrong & When Cheaper Options Fail
1. Ignoring Temperature Compensation
- What happens: A load cell rated only to ±0.5 %FS temperature drift can introduce tens of kilograms of error in a 500 kg system when ambient temperature swings from 15 °C to 35 °C— common in Australian summer‑winter cycles.
- How the Taylor 5789F helps: Built‑in ±0.1 %FS compensation keeps the error under 0.5 kg across the full range.
2. Selecting the Lowest‑Cost Cell Without Considering Noise
- Scenario: A cheap 0.5 %FS cell with 1.2 µV RMS noise is purchased for a precision pharmaceutical press. The resulting signal‑to‑noise ratio forces the lab to add expensive external filters.
- Result: The total cost ends up 30 % higher than buying the higher‑spec Taylor 5789F outright.
3. Using the Wrong Form Factor
- Risk: Mounting a compression‑type cell in a shear‑beam slot introduces bending stresses that can cause premature fatigue.
- Best practice: Match the mounting style to the load path. The Taylor 5789F’s double‑hole shear‑beam flange is designed for side‑load applications; for axial loads, choose a column‑type cell.
4. Skipping Calibration After Installation
- Consequence: Even a perfectly spec’d cell can drift due to mounting strain or cable flex.
- Solution: Perform in‑situ calibration using a certified dead‑weight set within 24 h of installation. LoadCellShop Australia provides a free calibration service for bulk orders (5 + units).
5. Over‑relying on “Bulk Discount” for Improper Parts
- Reality check: A 5 % bulk discount is valuable, but buying the wrong capacity or the wrong material (e.g., carbon steel in a corrosive environment) results in early failure and higher lifecycle costs.
Product Recommendations – Complementary Load Cells from LoadCellShop Australia
Below are three load cells that pair well with the taylor 5789f for projects requiring multiple ranges or special environments. All are stocked at LoadCellShop Australia (operated by Sands Industries) with the same free‑consultation service and 5 % bulk‑order discount.
| Model | Capacity | Accuracy Class | Material | Application Fit | Approx. Price (AUD) | SKU |
|---|---|---|---|---|---|---|
| Sensing 5000‑3kN | 0 – 3 kN | Class 0.3 | 304 SS | Mid‑range weighing, feed‑rate control in food processing | $1 200 | SNS‑5000‑3K |
| Honeywell 2410‑1000 | 0 – 1 kN | Class 0.2 | Al‑7075 (lightweight) | Aerospace component testing, high‑speed dynamic load measurement | $1 350 | HNW‑2410‑1K |
| Omega LB‑500 | 0 – 500 N | Class 0.5 | 316 SS | Low‑force laboratory rigs, micro‑force research (e.g., MEMS testing) | $980 | OMG‑LB‑500 |
Why Each Is Suitable
- Sensing 5000‑3kN – Offers a slightly lower capacity with comparable accuracy (Class 0.3) and an identical IP 68 rating, making it perfect for secondary weigh stations where space is limited. Its compact footprint fits into the same mounting brackets as the Taylor 5789F, enabling seamless system expansion.
- Honeywell 2410‑1000 – The lightweight aluminium body reduces inertial load on high‑speed test rigs, while still delivering Class 0.2 accuracy. Ideal when the dynamic response is more critical than corrosion resistance.
- Omega LB‑500 – Provides a micro‑range (up to 0.5 kN) for tests that fall below the lower limit of the 5789F. Its higher Class 0.5 error is acceptable for low‑force applications where absolute precision is less critical.
When Each Is NOT Ideal
- Sensing 5000‑3kN – Not suitable for >3 kN loads; overspecifying capacity will increase hysteresis and reduce resolution compared to the 5789F.
- Honeywell 2410‑1000 – The aluminium body corrodes quickly in salty or acidic environments; avoid for offshore or food‑processing use.
- Omega LB‑500 – The higher noise floor (≈1 µV) makes it unsuitable for high‑precision dynamic testing; pair with a high‑grade amplifier if used.
Alternative Recommendations
If you need >10 kN capacity with similar noise performance, consider the StrainTech C3‑10K (Class 0.2, 316 SS, IP 67, approx. $2 200, SKU ST‑C3‑10K). For ultra‑low‑force (<10 N) measurement, the MicroForce MF‑10 (Class 0.1, ceramic body, 0‑10 N, $860, SKU MF‑10) offers sub‑µV noise.
Installation & Calibration – A 5‑Step Checklist
Even the best load cell can deliver poor data if installed incorrectly. Follow this concise checklist for the taylor 5789f (and the complementary cells above).
- Verify Mounting Surface – Ensure the mounting flange is perfectly flat (tolerance ≤ 0.02 mm). Use a precision torque wrench to tighten bolts to 7 Nm.
- Apply Correct Pre‑Load – For shear‑beam cells, a pre‑load of 5 % of full scale stabilises the strain gauge. Use calibrated dead‑weights.
- Connect Shielded Cable – Route the 4‑core shielded cable away from high‑current lines. Terminate with a 4‑pin M12 connector (provided).
- Supply Excitation Voltage – Deliver a stable 10 V ± 0.5 V from a regulated power supply. Verify voltage with a multimeter before and after connection.
- Perform Full‑Scale Calibration – Apply at least three calibrated loads (e.g., 0 %, 50 %, 100 % FS) and record output. Upload the calibration curve to your DAQ or PLC.
Tip: Record ambient temperature during calibration; the Taylor 5789F’s temperature compensation is temperature‑based, and the recorded temperature must be logged for traceability.
Conclusion & Next Steps
The taylor 5789f stands out in the Australian market for its blend of high Class 0.2 accuracy, ultra‑low noise floor, robust IP 68 protection, and competitive pricing. Our sound tests confirm it exceeds ISO 13373‑2 limits, providing a cleaner signal than most mainstream alternatives. By understanding where cheaper options fail—especially in temperature stability and noise performance—you can avoid costly re‑engineering later.
For engineers, procurement managers, OEM integrators, lab technicians, QA teams, and industrial buyers, the decisive factors are now clear:
- Choose the Taylor 5789F when you need up to 5 kN capacity with tight tolerances.
- Pair it with Sensing 5000‑3kN or Honeywell 2410‑1000 for multi‑range systems.
- Rely on LoadCellShop Australia’s free consultation, 5 % bulk‑order discount, and custom‑cell options to tailor the solution to your exact specifications.
Ready to elevate your force‑measurement capability? Contact LoadCellShop Australia today for a no‑obligation technical discussion, request a quote, or order directly through our secure online shop.
- Phone: +61 4415 9165 | +61 477 123 699
- Email: sales@sandsindustries.com.au
- Address: Unit 27/191 McCredie Road, Smithfield NSW 2164, Australia
🔗 Explore the full range now: https://loadcellshop.com.au/shop
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