The History of Scales

triple-beam-balance

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If you were to travel back in time and show an ancient street merchant a digital weighing scale, he would have no idea what to do with it. Yet over the entire course of history, scales have been just as important to the economy as they are today, which is why people have always strived—and continue to strive—for more accurate measurements.

Ancient Measurements

Weight

Weight measurements and scales have followed a very similar path. Some of the earliest examples of weight measurement were a simple rod that was suspended by a string in the middle. A pan was attached to each end and the product that needed to be placed in one pan, while stones representing a known weight were added to the other until the rod was balanced.

In fact, many of our earliest known written histories dwell on the requirement for society to use “true weights.”

The most ancient scales were rudimentary balances consisting of a lever with two pans suspended at equal distances from the fulcrum. When an item—such as a sack of gold coins—needed to be weighed, it would be placed in one of the pans. Known weights would then be added to and taken away from the opposite pan until the lever was perfectly balanced in a horizontal position. By calculating the total of the known weights, it was possible to determine the weight of the object in the other pan.

This system and similar variations were used until the late 1700s when new weighing technologies were invented. However, these inventions were not as accurate as the electronic systems that were designed and perfected in the 20th and 21st centuries.

The Triple-Beam Balance

More recently, the much more practical and intricate triple-beam balance was created. This device also uses a lever system in which the force on one side of the fulcrum is balanced with the force on the other side of the fulcrum.

Unlike the original simple balance, however, the triple-beam balance takes advantage of the concept that a mass further away from the fulcrum of the lever creates more force on the lever than a mass that is closer to the lever.

So rather than requiring equivalent weights on both sides of the lever to put the balance in equilibrium, the triple-beam balance is used by moving smaller weights closer and further from the fulcrum to balance out the weight of the object on the opposite side of the lever.

It’s likely that you’ve used this type of scale in your middle or high school physical science class.

Analog Scales

The next innovation was an analog scale called a spring scale, which relies on the concept that a force placed on a spring will stretch the spring a known distance its “spring constant” is known.

An indicator on the spring will move up and down a set distance against a gauge, which is marked with various weight measurements. When the force of the spring and the force of the object being weighed are in equilibrium, the correct weight can be read.

The most common type of spring scale is the bathroom scale, which combines the force of four levers coming from each corner of the scale to stretch a spring and spin a gauge.

Quick Timeline of Scale Innovation

  • 3100 BC – Balance scales used in Ancient Egypt
  • 1770 – Spring scale invented by Richard Salter
  • 1800s – Triple-beam balance introduced
  • 1900’s – Analog bathroom and postal scales adopted
  • Late 1900’s – Strain gauge digital scales dominate industry

Today – SAW technology enables ultra-precision scales with 1:100,000 resolution

Analog Scales in Today’s World

Analog scales are a perfect solution when a weight measurement doesn’t have to be very precise. They can determine a person’s body weight to within a pound or measure a serving of meat to within a few ounces.

However, they aren’t accurate enough for many industrial processes that require a higher level of precision. While a spring scale may have a resolution of 1 part in 100, industrial processes commonly require resolutions of 1 part in 5,000 or higher.

Digital Scales

Since their inception, digital scales have taken over as the most precise measuring devices and are by far the mostly widely used in industry. These electronic scales include bench, platform, floor, drum and cylinder scales.

The weight transducer used in digital industrial scales is called a strain gauge load cell. The load cell is a block of metal that is shaped in a way so that it bends, much like a spring, in a very predictable manner when a force acts upon it. Additionally, like a spring, when the force is removed, the load cell moves back to its original configuration.

Attached to the load cell are several strain gauges. These resistors are made up of folds of flat metal. When the load cell bends and the strain gages are stretched, their resistance changes proportional to the amount of force acting on the load cell. The output signal from the strain gages is sent to an ADC (analog-to-digital converter), which outputs a final weight reading.

Ultra Precision Scales

Ordinary strain gauge digital scales have resolutions of about 1 part in 5,000 and an accuracy of about 1/10 of 1%. However, this still isn’t as precise as some industries require, which is why we’ve developed a new weighing technology called Surface Acoustic Wave (SAW) and designed a new line of Ultra Precision industrial scales.

These industrial scales use two semiconductor substrates and SAW transducers. When weight is applied to the scale, it creates a bulk wave that travels between the transducers. The frequency of oscillation of these devices is directly proportional to the weight on the scale platform. By measuring this digitally, we’re able to offer resolutions of 1 part in 100,000 and accuracy of 1/100 of 1%.

These scales are particularly useful in situations where high precision is necessary, such as check weighing, small parts counting, accurate filling, flow rate monitoring and polymer production. The pharmaceutical, chemical, paint and many other industries rely on this Ultra Precision technology.

Ready for the Next Evolution in Weighing?

From ancient balances to cutting-edge SAW technology, the weighing industry has come a long way — and Arlyn Scales is leading that progress.

Our Ultra Precision Scales, powered by patented Surface Acoustic Wave technology, deliver:

  • Resolution up to 1:100,000
  • High stability in industrial environments
  • Seamless integration with USB, Wi-Fi, Ethernet, and cloud platforms
  • Accuracy you can trust — even in critical batching, filling, and monitoring workflows

Discover why leading manufacturers, labs, and logistics teams rely on Arlyn to push their precision further. Talk to a scale specialist today!